パワフルメジャーリーグ2

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出典: 標準

東京大学　マイクロ・ナノ多機能デバイス連携研究機構　北森グループ Menu 研究内容教育社会連携・社会貢献メンバー論文・解説・書籍・特許等招待講演学会発表受賞・表彰等研究室内イベントリンク Home English 日本語 Home English 日本語 Home >&＃160;論文・解説・書籍・特許等論文・解説・書籍・特許等論文解説書籍特許等論文1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020 2021 2022 2023in press 2023Nanofluidic analytical system integrated with nanochannel open/close valves for enzyme-linked immunosorbent assayHiroki Sano, Yutaka Kazoe, Ryoichi Ohta, Hisashi Shimizu, Kyojiro Morikawa and Takehiko KitamoriLab on a Chip, 23, 727-736 (2023)Enzyme-linked immunosorbent assay using thin-layered microfluidics with perfect capture of the target proteinAdelina Smirnova, Ryoichi Ohta, Emi Mori, Hisashi Shimizu, Kyojiro Morikawa and Takehiko KitamoriAnalytical Method, 15, 675-684 (2023)Stability of enzyme immobilized on the nanofluidic channel surfaceKoki Yamamoto, Kyojiro Morikawa, Chihchen Chen, Takehiko KitamoriAnalytical Sciences, 39, 251-255 (2023). selected as Analytical Sciences Hot Articles 2023Fused silica microchannel fabrication with smooth surface and high etching selectivityKyojiro Morikawa, Po-yin Chen, Hai Linh Tran, Yutaka Kazoe, Chihchen Chen and Takehiko KitamoriJournal of Micromechanics and Microengineering, 33, 047001 (2023)Quantitative characterization of liquids flowing in geometrically-controlled sub-100 nm nanofluidic channelsYutaka Kazoe, Keisuke Ikeda, Kensuke Mino, Kyojiro Morikawa, Kazuma Mawatari, Takehiko KitamoriAnalytical Sciences, 39, 779-784, (2023). selected as Analytical Sciences Hot Articles 2023Nanofluidic gas/liquid switching utilizing a nanochannel open/close valve based on glass deformationHiroki Sano, Yutaka Kazoe, Kyojiro Morikawa and Takehiko KitamoriJournal of Micromechanics and Microengineering, 33, 085007, (2023)Room-temperature bonding of glass chips via PTFE-assisted plasma modification for nanofluidic applicationsQiushi Kang , Chenxi Wang , Kaimeng Liu and Takehiko KitamoriLab on a Chip, 23, 2710-2719, (2023)2022Characterization of Pressure-Driven Water Flows in Nanofluidic Channels by Mass FlowmetryYutaka Kazoe, Sho Kubori, Kyojiro Morikawa, Kazuma Mawatari, and Takehiko KitamoriAnalytical Science, 38, 281–287 (2022). selected as Analytical Sciences Hot Articles 2022Picoliter liquid handling at gas/liquid interface by surface and geometry control in a micro-nanofluidic deviceKyojiro Morikawa, Shin-ichi Murata, Yutaka Kazoe, Kazuma Mawatari, Takehiko Kitamori,Journal of Micromechanics and Microengineering, 32, 024001 (7pp), (2022)Water structure in 100 nm nanochannels revealed by nano X-ray diffractometry and Raman spectroscopyJun Shirai, Koji Yoshida, Hiroki Koreeda, Takehiko Kitamori, Toshio Yamaguchi, Kazuma MawatariJournal of Molecular Liquids, 350, 118567, (2022)Accelerated protein digestion and separation with picoliter volume utilizing nanofluidicsKoki Yamamoto, Kyojiro Morikawa, Hisashi Shimizu, Hiroki Sano, Yutaka Kazoe, Takehiko KitamoriLab on a Chip, 22, 1162-1170, (2022). selected as Lab on a Chip HOT Articles 2022Picoliter liquid operations in nanofluidic channel utilizing an open/close valve with nanoscale curved structure mimicking glass deflectionHiroki Sano, Yutaka Kazoe, Kyojiro Morikawa and Takehiko KitamoriJournal of Micromechanics and Microengineering, 32, 055009(11pp), (2022)Femtoliter-Droplet Mass Spectrometry Interface Utilizing Nanofluidics for Ultrasmall and High-Sensitivity AnalysisYuto Takagi, Yutaka Kazoe, Kyojiro Morikawa, and Takehiko KitamoriAnalytical Chemistry, 94, 10074-10081 (2022)Proton diffusion and hydrolysis enzymatic reaction in 100 nm scale biomimetic nanochannelsTakashi Saruko, Kyojiro Morikawa, Takehiko Kitamori, Kazuma MawatariBiomicrofluidics, 16, 044109 (2022)Kinetics of Enzymatic Reactions at the Solid/Liquid Interface in Nanofluidic ChannelsKoki Yamamoto, Kyojiro Morikawa, Hiroyuki Imanaka, Koreyoshi Imamura, Takehiko KitamoriAnalytical Chemistry, 94, 15686−15694, (2022)2021Super-Resolution Defocusing Nano-Particle Image Velocimetry Utilizing Spherical Aberration for Nanochannel FlowsYutaka Kazoe, Kazuki Shibata, Takehiko KitamoriAnalytical Chemistry, 93 (39), 13260–13267, (2021)B cell depletion inhibits fibrosis via suppressing pro-fibrotic macrophage differentiation in a mouse model of systemic sclerosisHiroko Numajiri, Ai Kuzumi, Takemichi Fukasawa, Satoshi Ebata, Asako Yoshizaki-Ogawa, Yoshihide Asano, Yutaka Kazoe, Kazuma Mawatari, Takehiko Kitamori, Ayumi Yoshizaki, Shinichi SatoArthritis & Rheumatology, 73(11), 2086–2095, (2021)Nano-bubble Valve Shun Furukawa, Kazuma Mawatari, Yoshiyuki Tsuyama, Kyojiro Morikawa and Takehiko KitamoriMicrofluidics and Nanofluidics, 25, 24(8pp), (2021)Isotope Effect in the Liquid Properties of Water Confined in 100 nm Nanofluidic Channels Kazuma Mawatari, Kohei Isogai, Kyojiro Morikawa, Hiroshi Ushiyama, Takehiko KitamoriThe Journal of Physical Chemistry B, 125, 3178-3183, (2021)Development of microfluidic droplet shooter and its application to interface for mass spectrometry Yutaka Kazoe, Yusuke Shimizu, Kyojiro Morikawa, Yasushi Terui, Takashi Irie, Takehiko KitamoriSensors and Actuators: B, 340, 129957(9pp), (2021)Numerical Modeling of Photothermal Effect in Nanofluidic Channel Hisashi Shimizu and Takehiko KitamoriMicrofluidics and Nanofluidics, 25, 60 (2021)Generation of Femtoliter Liquid Droplets in Gas Phase by Microfluidic Droplet ShooterYuto Takagi, Yutaka Kaoze, and Takehiko KitamoriMicrofluidics and Nanofluidics, 25, 74(8pp) (2021)Metal-free Fabrication of Fused Silica Extended Nanofluidic Channel to Remove Artifacts in Chemical AnalysisKyojiro Morikawa, Ryoichi Ohta, Kazuma Mawatari, and Takehiko KitamoriMicromachines, 12, 917(10pp) (2021)Interleukin-31 promotes fibrosis and T helper 2 polarization in systemic sclerosisAi Kuzumi, Ayumi Yoshizaki, Kazuki Matsuda, Hirohito Kotani, Yuta Norimatsu, Maiko Fukayama, Satoshi Ebata, Takemichi Fukasawa, Asako Yoshizaki-Ogawa, Yoshihide Asano, Kyojiro Morikawa, Yutaka Kazoe, Kazuma Mawatari, Takehiko Kitamori, and Shinichi SatoNature Communications, 12, 5947(18pp), (2021)Surface Patterning of Closed Nanochannel Using VUV Light and Surface Evaluation by Streaming CurrentKyojiro Morikawa, Haruki Kazumi , Yoshiyuki Tsuyama, Ryoichi Ohta and Takehiko KitamoriMicromachines, 12, 1367(11pp), (2021)Stable Formation of aqueous/organic parallel two-phase flow in nanochannels with partial surface modification Hiroki Sano, Yutaka Kazoe, and Takehiko KitamoriAnalytical Science, 37,1611-1616,(2021)Single-cell-level protein analysis revealing the roles of autoantigen-reactive B lymphocytes in autoimmune disease and the murine modelTakemichi Fukasawa, Ayumi Yoshizaki, Satoshi Ebata, Asako Yoshizaki-Ogawa, Yoshihide Asano, Atsushi Enomoto, Kiyoshi Miyagawa, Yutaka Kazoe, Kazuma Mawatari, Takehiko Kitamori, Shinichi SatoeLife, 10, e67209 (21pp) (2021)2020Femtoliter Volumetric Pipette and Flask Utilizing NanofluidicsTatsuro Nakao, Yutaka Kazoe, Kyojiro Morikawa, Ling Lin, KazumaMawatari, and Takehiko KitamoriAnalyst, 145, 2669 &＃8211; 2675 (2020) Ultrasensitive detection of nonlabelled bovine serum albumin using photothermal optical phase shift detection with UV excitationHisashi Shimizu, Sigenori Takeda, Kazuma Mawatari, Takehiko KitamoriAnalyst, 145, 2580-2585 (2020)Picoliter enzyme reactor on a nanofluidic device exceeding the bulk reaction rateKoki Yamamoto, Kyojiro Morikawa, Hiroyoki Imanaka, Koreyoshi Imamura, Takehiko KitamoriAnalyst, 145, 5801-5807, (2020)Lipid Bilayer-Modified Nanofluidic Channels of Sizes with Hundreds of Nanometers for Characterization of Confined Water and Molecular/Ion TransportYutaka Kazoe, Kazuma Mawatari, Lixiao Li, Hisaki Emon, Naoya Miyawaki, Hiroyuki Chinen, Kyojiro Morikawa, Ayumi Yoshizaki, Petra S. Dittrich, Takehiko KitamoriThe Journal of Physical Chemistry Letters, 11, 5756-5762 (2020)Implementation of a Nanochannel Open/Close Valve into a Glass Nanofluidic DeviceHiroki Sano, Yutaka Kazoe, Kyojiro Morikawa, and Takehiko KitamoriMicrofluidics and Nanofluidics, 24, 78(11pp), (2020)Advanced Top-Down Fabrication for a Fused Silica Nanofluidic DeviceKyojiro Morikawa, Yutaka Kazoe, Yuto Takagi, Yoshiyuki Tsuyama, Yuriy Pihosh, Takehiko Tsukahara, Takehiko KitamoriMicromachines, 11, 995(11pp), (2020)Fabrication of Infrared-Compatible Nanofluidic Devices for Plasmon-Enhanced Infrared Absorption SpectroscopyThu Hac Huong Le, Takumi Matsushita, Ryoichi Ohta, Yuta Shimoda, Hiroaki Matsui and Takehiko KitamoriMicromachines, 11, 1062(11pp), (2020)Conversion Reaction in the Binder-Free Anode for Fast-Charging Li-Ion Batteries Based on WO3 NanorodsRaman Bekarevich, Yuriy Pihosh, Yoshinori Tanaka, Kei Nishikawa, Yoshitaka Matsushita, Takanobu Hiroto, Hirohito Ohata, Takahisa Ohno, Tsutomu Minegishi, Masakazu Sugiyama, Takehiko Kitamori, Kazutaka Mitsuishi, and Kazunori TakadaACS Appl. Energy Mater., 3, 7, 6700–6708 (2020)Fabrication of Infrared-Compatible Nanofluidic Devices for Plasmon-Enhanced Infrared Absorption SpectroscopyThu Hac Huong Le, Takumi Matsushita, Ryoichi Ohta, Yuta Shimoda, Hiroaki Matsui and Takehiko KitamoriMicromachines, 11, 1062(11pp), (2020)2019Cytokine analysis at countable number of molecules from living single cells on nanofluidic devicesTatsuro Nakao, Yutaka Kazoe, Emi Mori, Kyojiro Morikawa, Takemichi Fukasawa, Ayumi Yoshizaki and Takehiko KitamoriAnalyst, 144, 7200-7208 (2019)Femtoliter Gradient Elution System for Liquid Chromatography Utilizing Extended-Nano FluidicsHisashi Shimizu, Kouto Toyoda, Kazuma Mawatari, Shigeru Terabe, and Takehiko KitamoriAnalytical Chemistry, 91, 3009-3014 (2019)Detachable glass micro/nanofluidic deviceRyoichi Ohta, Kazuma Mawatari, Tomoaki Takeuchi, Kyojiro Morikawa, and Takehiko KitamoriBiomicrofluidics, 13, 024104(2019)Femto-liter Nanofluidic Valve Utilizing Glass Deformation Yutaka Kazoe, Yuriy Pihosh, Hitomi Takahashi, Takeshi Ohyama, Hiroki Sano, Kyojiro Morikawa, Kazuma Mawatari, Takehiko KitamoriLab on a Chip, 19, 1686-1694(2019)Ferroelectric Extended Nanofluidic Channels for Room-Temperature Microfuel CellsYuriy Pihosh, Yutaka Kazoe, Kazuma Mawatari, Hangyeol Seo, Osamu Tabata, Toshiyuki Tsuchiya, Kenji Kitamura, Masahiro Tosa, Ivan Turkevych, and Takehiko KitamoriAdvanced Materials Technologies, 1900252(2019)Parallel multiphase nanofluidics utilizing nanochannels with partial hydrophobic surface modification and application to femtoliter solvent extractionYutaka Kazoe, Takuya Ugajin, Ryoichi Ohta, Kazuma Mawatari and Takehiko Kitamori Lab on a Chip, 19, 3844 &＃8211; 3852 (2019)Enzyme-Linked Immunosorbent Assay Utilizing Thin-Layered MicrofluidicsTatsuro Nakao, Kazuma Mawatari, Yutaka Kazoe, Emi Mori, Hisashi Shimizu and Takehiko Kitamori Analyst, 144, 6625 &＃8211; 6634 (2019)2018Single-Molecule ELISA Device utilizing NanofluidicsKentaro Shirai, Kazuma Mawatari, Ryoichi Ohta, Hisashi Shimizu, Takehiko KitamoriAnalyst(cover), 143, 943-948(2018)Nano X-ray diffractometry device for nanofluidicsKazuma Mawatari,Hiroki Koreeda,Koji Ohara,Shinji Kohara,Koji Yoshida,Toshio Yamaguchi,and Takehiko KitamoriLab on a Chip, 18,1259-1264(2018)Time resolution effect on the apparent particle dynamics confined in a nanochannel evaluated by the single particle tracking subject to Brownian motionItsuo Hanasaki, Yutaka Kazoe, Takehiko KitamoriMicrofluidics and Nanofluidics, 22,56(2018)Metamaterials-Enhanced Infrared Spectroscopic Study of Nanoconfined Molecules by Plasmonics-Nanofluidics Hydrid DeviceLe Thu, Morita Akihiro, Mawatari Kazuma, Kitamori Takehiko, Tanaka TakuoACS photonics, 5(8),3179-3188(2018)Transport of a Micro Liquid Plug in a Gas-Phase Flow in a MicrochannelYutaka Kazoe, Takumi Matsuno, Ippei Yamashiro, Kazuma Mawatari, and Takehiko KitamoriMicromachines, 9,423(2018)Rapid alteration of serum interleukin-6 levels may predict the reactivity of i.v. cyclophosphamide pulse therapy in systemic sclerosis-associated interstitial lung diseaseHiroko Numajiri, Ayumi Yoshizaki, Takemichi Fukazawa, Satoshi Ebata, Kouki Nakamura, Takashi Yamashita, Ryosuke Saigusa, Shunsuke Miura, Megumi Hirabayashi, Asako Yoshizaki, Hayakazu Sumida, Yoshihide Asano, Yutaka Kazoe, Kazuma Mawatari, Takehiko Kitamori, Shinichi Sato The Journal of Dermatology, 45, 1221-1224, (2018).2017Micro heat pipe device utilizing extended nanofluidicsChenxi Wang, Yutaka Kazoe, Kyojiro Morikawa, Hisashi Shimizu, Yuriy Pihosh, Kazuma Mawatari and Takehiko KitamoriRSC Adv., 7,50591-505597(2017)From Extended-Nano Fluidics to an Autonomous Solar Light Driven Micro Fuel Cell DeviceYuriy Pihosh, Jin Uemura, Ivan Turkevych, Kazuma Mawatari, Yutaka Kazoe, Adelina Smirnova and Takehiko KitamoriAngew. Chem. Int. Ed., 56,8130-8133(2017)Thermo-Optical Characterization of Photothermal Optical Phase Shift Detection in Extended-Nano Channels and UV Detection of BiomoleculesHisashi Shimizu, Naoya Miyawaki, Yoshihiro Asano, Kazuma Mawatari, and Takehiko KitamoriAnal. Chem., 89(11),6043–6049(2017)Sensitive and rapid assay of BNP in patient blood by micro-ELISAEmi Mori, Toshinori Oohashi, Hisashi Imai, Kazuma Mawatari, and Takehiko KitamoriAnalytical method, 9,2830-2834(2017)Micro/extended-nano Sampling Interface from Living Single CellL. Lin, K. Mawatari, K. Morikawa, Y. Pihosh, A. Yoshizaki, T. KitamoriAnalyst, 142,1689-1696(2017)Clogging-Free Irreversible Bonding of Polycarbonate Membranes to Glass Microfluidic DevicesChenxi Wang, Xiaofang Gao, Kazuma Mawatari, and Takehiko KitamoriJournal of The Electrochemical Society, 164,B3087-B3090(2017)A Photothermal Spectrometer for Fast and Background-Free Detection of Individual Nanoparticles in FlowRichard M. Maceiczyk, Hisashi Shimizu, David Müller, Takehiko Kitamori, and Andrew J. deMelloAnal. Chem., 89,1994-1999(2017)Contribution of Soluble forms of programmed death 1 and programmed death ligand 2 to disease severity and progression in systemic sclerosisTakemichi Fukazawa, Ayumi Yoshizaki, Satoshi Ebata, Kouki Nakamura, Ryosuke Saigusa, Syunsuke Miura, Takashi Yamashita, Megumi Hirabayashi, Yohei Ichimura, Takashi Taniguchi, Yoshihide Asano, Hisashi Shimizu, Yutaka Kazoe, Kazuma Mawatari, Takehiko Kitamori, Shinichi Sato Arthritis & Rhueumatology, 69, 1879-1890, (2017).2016An Easy-to-Use Polystyrene Microchip-based Cell Culture SystemH. Tazawa, S. Sunaoshi, M. Tokeshi, T. Kitamori, R. Ohtani-KanekoAnal Sci., 32,349-353(2016)Cell sheet mechanics: how geometrical constraints induce the detachment of cell sheets from concave surfacesTadahiro Yamashita, Philip Kollmannsberger, Kazuma Mawatari, Takehiko Kitamori*, Viola Vogel*(* Corresponding authors)Acta Biomaterialia, 45,85-97(2016)Low-temperature bonding process for the fabrication of hybrid glass–membrane organ-on-a-chip devicesKyall J. Pocock ; Xiaofang Gao ; Chenxi Wang ; Craig Priest ; Clive A. Prestidge ; Kazuma Mawatari ; Takehiko Kitamori ; Benjamin ThierryJournal of Micro/Nanolithography, MEMS, and MOEMS, 15(4),044502(2016,12)Whole blood analysis using microfluidic plasma separation and enzyme-linked immunosorbent assay devicesHisashi Shimizu, Mariko Kumagai, Emi Mori, Kazuma Mawatari, and Takehiko KitamoriAnalytical Methods, 42,7597-7602(2016,8)On-Chip Step-Mixing in a T-Nanomixer for Liquid Chromatography in Extended-NanochannelsAdelina Smirnova, Hisashi Shimizu, Yuriy Pihosh, Kazuma Mawatari, and Takehiko KitamoriAnal. Chem., 88,10059(2016)High-Pressure Acceleration of Nanoliter Droplets in the Gas Phase in a MicrochannelYutaka Kazoe, Ippei Yamashiro, Kazuma Mawatari, Takehiko KitamoriMicromachines, 7,142(2016)Femtoliter High-Performance Liquid Chromatography Using Extended-Nano Channels Hisashi Shimizu, Kyojiro Morikawa, Yilin Liu, Adelina Smirnova, Kazuma Mawatari and Takehiko KitamoriAnalyst, 141, 6068-6072(2016)Tandem photovoltaic–photoelectrochemical GaAs/InGaAsP–WO3/BiVO4 device for solar hydrogen generationSonya Kosar, Yuriy Pihosh, Ivan Turkevych, Kazuma Mawatari, Jin Uemura, Yutaka Kazoe, Kikuo Makita, Takeyoshi Sugaya, Takuya Matsui, Daisuke Fujita, Masahiro Tosa, Yaroslav M. Struk, Michio Kondo, and Takehiko KitamoriJapanese Journal of Applied Physics, 55,04ES01(2016)An electric generator using living Torpedo electric organs controlled by fluid pressure-based alternative nervous systemsYo Tanaka, Shun-ichi Funano, Yohei Nishizawa, Norihiro Kamamichi, Masahiro Nishinaka, Takehiko KitamoriScientific Reports, 6,25899(2016)Living Single Cell Analysis Platform Utilizing Microchannel, Single Cell Chamber, and Extended-Nano Channel L. Lin, K. Mawatari, K. Morikawa, T. KitamoriAnal. Sci., 32,75-78(2016)2015Reversed-phase Chromatography in an Extended Nanospace: Separating Amino Acids in Short and Long Nanochannels Adelina Smirnova, Hisashi Shimizu, Kazuma Mawatari, Takehiko KitamoriAnal. Sci., 31(11),1201-1204(2015)Reversed-phase chromatography in extended-nano space for the separation of amino acids Adelina Smirnova, Hisashi Shimizu, Kazuma Mawatari, Takehiko KitamoriJOURNAL OF CHROMATOGRAPHY A, 1418,224-227(2015)Spontaneous Packaging and Hypothermic Storage of Mammalian Cells with a Cell-Membrane-Mimetic Polymer Hydrogel in a Microchip Yan Xu, Kazuma Mawatari, Tomohiro Konno, Takehiko Kitamori, Kazuhiko IshiharaACS APPLIED MATERIALS & INTERFACES, 7(41),23089-23097(2015) Keto-Enol Tautomeric Equilibrium of Acetylacetone Solution Confined in Extended Nanospaces Takehiko Tsukahara, Kyosuke Nagaoka, Kyojiro Morikawa, Kazuma Mawatari, Takehiko KitamoriJ. Phys. Chem. B,119,14750-14755(2015) Photocatalytic generation of hydrogen by core-shell WO 3 /BiVO 4 nanorods with ultimate water splitting efficiency Yuriy Pihosh, Ivan Turkevych, Kazuma Mawatari, Jin Uemura, Yutaka Kazoe, Sonya Kosar, Kikuo Makita, Takeyoshi Sugaya,Takuya Matsui, Daisuke Fujita, Masahiro Tosa, Michio Kondo, and Takehiko KitamoriScientific Reports, 5,11141,1-9(2015)As of December 2016, this paper was selected by Scientific Reports to hilight in marketing campaigns to the scientific community and to receive a complimentary video abstracthttps://www.altmetric.com/details/13555272/videoBehavior of Nanoparticles in Extended Nanospace Measured by Evanescent Wave-Based Particle Velocimetry Yutaka Kazoe, Kazuma Mawatari, Takehiko KitamoriAnalytical Chemistry, 87,,4087-4091(2015)Dielectric Constant of Liquids Confined in the Extended Nanospace Measured by a Streaming Potential Method K. Morikawa, Y. Kazoe, K. Mawatari, T. Tsukahara, T. KitamoriAnalytical Chemistry, 87(3),1475-1479(2015)2014Novel Sub-100 nm Surface Chemical Modification by Optical Near-field Induced Photocatalytic Reaction H.H.Le, K.Mawatari, Y.Pihosh, T.Kawazoe, T.Yatsui, M.Ohtsu, T.KitamoriMicrofluidics and Nanofluidics, 17(4),751-758Nanostructured WO3/BiVO4 Photoanodes for Efficient Photoelectrochemical Water SplittingY.Pihosh, I. Turkevych, K.Mawatari, T.Asai, T.Hisatomi, J.Uemura, M.Tosa, K.Shimamura, J.Kubota, K.Domen, T.Kitamori Small, 10(18),3692-3699(2014)Ubiquitous Element Approach to Plasmonic Enhanced Photocatalytic Water Splitting: the Case of Ti@TiO2 Core-shell NanostructureY.Pihosh, I.Turkevych, K.Mawatari, N.Fuukuda, R.Ohta, M.Tosa, K.Shimamura, E. Villora, T. KitamoriNanotechnology, 25(31),315402(2014)Extended Nanofluidic Immunochemical Reaction with Femtoliter Sample VolumesKentaro Shirai, Kazuma Mawatari, Takehiko KitamoriSmall, 10(8),1514-1522(2014)Determination of Cattle Foot-and-Mouth Disease Virus by micro-ELISA system Y.Dong, Y. Xu, Z.Liu, Y. Fu, T.Ohashi, K.Mawatari, T.KitamoriAnal.Sci., 30(3) ,359-363(selected as Hot Article)A competitive micro fl uidic immunological clenbuterol analysis using a microELISA system Q.Chen, J.Liu, S.Wang, L.Zhang, Y.Dong, K.Mawatari, T.Kitamori RSC Advances, 4(75),39894-39896(2014)Detection of zeptomole quantities of nonfluorescent molecules in a 10(1) nm nanochannel by thermal lens microscopyH.Le, K.Mawatari, H.Simizu,K.KitamoriAnalyst, 139(11),2721-2725(2014)(selected as Hot Article)Femtoliter-Scale Separation and Sensitive Detection of Nonfluorescent Samples in an Extended-Nano Fluidic DeviceHisashi Shimizu, Kazuma Mawatari and Takehiko KitamoriAnalyst, 139(9),2154-2157(2014)2013Evanescent Wave-Based Particle Tracking Velocimetry for Nanochannel FlowsYutaka Kazoe, Keizo Iseki, Kazuma Mawatari, Takehiko KitamoriAnalytical Chemistry, 85,10780-10786(2013)Numerical Simulation of Proton Distribution with Electric Double Layer in Extended Nanospaces Chih-Chang Chang, Yutaka Kazoe, Kyojiro Morikawa, Kazuma Mawatari, Ruey-Jen Yang, Takehiko KitamoriAnalytical Chemistry, 85,4468-4474(2013).An active valve incorporated into a microchip using a high strain electroactive polymer Yo Tanaka, Tomohiro Fujikawa, Yutaka Kazoe, Takehiko KitamoriSensors and Actuators B: Chemical, 184,163-169(2013)Bonding of glass nanofluidic chips at room temperature by a one-step surface activation using an O2/CF4 plasma treatmentYan Xu, Chenxi Wang, Lixiao Li, Nobuhiro Matsumoto, Kihoon Jang, Yiyang Dong, Kazuma Mawatari, Tadatomo Suga, Takehiko KitamoriLab on a Chip, 13(6),1048-1052(2013)2012Femtoliter Droplet Handling in Nanofluidic Channels: A Laplace NanovalveKazuma Mawatari, Shogo Kubota, Yan Xu, Craig Priest, Rossen Sedev, John Ralston, Takehiko KitamoriAnalytical Chemistry, 84 (24),10812-10816(2013)Desktop near-field thermal lens microscope for thermo-optical detection in microfluidicsAdelina Smirnova, Kazuma Mawatari, and Takehiko KitamoriElectrophoresis, 33,2749-2751 (2012)Reply to the Comment to development of Measurement Technique for Ion Distribution in Extended Nanochannel by Super Resolution-Laser Induced FluorescenceYutaka Kazoe, Chih-Chang Chang, Kazuma Mawatari, and Takehiko KitamoriAnalytical Chemistry, 84,10855-10855 (2012)Selective cell capture and analysis using shallow antibody-coated microchannels Kihoon Jang, Yo Tanaka, Jun Wakabayashi, Reina Ishii, Sato Kae, Kazuma Mawatari, Mats Nilsson, Takehiko KitamoriBiomicrofluidics, 6(4),044117(2012)Micropatterning of biomolecules on a glass substrate in fused silica microchannels by using photolabile linker-based surface activationKihoon Jang, Yan Xu, Kae Sato, Yo Tanaka, Kazuma Mawatari, Takehiko KitamoriMicrochimica Acta, 179,49-55(2012)Fluid Mixing Using AC Electrothermal Flow on Meandering Electrodes in a MicrochannelNaoki Sasaki, Takehiko Kitamori, Haeng-Boo KimElectrophoresis, 33(17),2668-2673(2012)Viscosity and Wetting Property of Water Confined in Extended Nanospace Simultaneously Measured from Highly-Pressurized Meniscus MotionLixiao Li, Yutaka Kazoe,Kazuma Mawatari,Yasuhiko Sugii,Takehiko KitamoriThe Journal of Physical Chemistry Letters, 3,2447-2452(2012)A Palmtop-Sized Microfluidic Cell Culture System Driven by a Miniaturized Infusion PumpN. Sasaki, M. Shinjo, S. Hirakawa, M. Nishinaka, Y. Tanaka, K. Mawatari, T. Kitamori, K. SatoElectrophoresis, 33(12),1729-1735(2012)Direct measurements of the saturated vapor pressure of water confined in extended nanospaces using capillary evaporation phenomenaT.Tsukahara, T. Maeda, A. Hibara, K. Mawatari, T. KitamoriRSC advances, 2,3184-3186(2012)High Resolution Separation by Pressure-Driven Liquid Chromatography in Meander Extended-NanochannelsR. Ishibashi, K.Mawatari, T.KitamoriJournal of Chromatography A, 1238,152-155(2012)Highly efficient and ultra small volume separation by pressure driven liquid chromatography in extended nanochannelsR. Ishibashi, K.Mawatari, T.KitamoriSmall, 8(8),1237-1242(2012)(IF=7.3)Low-temperature direct bonding of glass nanofluidic chips using a two-step plasma surface activation processY. Xu, C. Wang, Y. Dong, L. Li, K. Jang, K. Mawatari, T. Suga, T. KitamoriAnalytical and Bioanalytical Chemistry, 402(3),1011-1018(2012)Enhancement of Proton Mobility in Extended Nanospace ChannelsH. Chinen, K. Mawatari, P. Yuriy, K. Morikawa, Y. Kazoe, T. Tsukahara, T. KitamoriAngew. Chem. Int. Ed., 51(15),3573-3577(2012)(selected as VIP)Shape of the Liquid-Liquid Interface in Micro Counter-Current FlowsArata Aota, Akihide Hibara, Yasuhiko Sugii, Takehiko KitamoriAnalytical Sciences, 28(1),9-12(2012)Detection of Nonfluorescent Molecules Using Differential Interference Contrast Thermal Lens Microscope for Extended-Nano Channel ChromatographyHisashi Shimizu, Kazuma Mawatari, Takehiko KitamoriJournal of Separation Science,34,2920-2924(2012)Development of a Pressure-Driven Injection System for Precisely Time Controlled AttoLiter Sample Injection into Extended NanochannelsRyo Ishibashi, Kazuma Mawatari, Katsuyoshi Takahashi, Takehiko KitamoriJournal of Chromatography A, 1228,51-56(2012)2011Development of microfluidic platform for single-cell secretion analysis using a direct photoactive cell-attaching method Kihoon Jang, Hong Trang Thi Ngo, Yo Tanaka, Yan Xu, Kazuma Mawatari, Takehiko KitamoriAnalytical Sciences, 27(10), 973(2011)(selected as Hot Articles and Cover illustration)Microchip-based Plasma Separation from Whole Blood via Axial Migration of Blood CellsArata AOTA, Susumu TAKAHASHI, Kazuma MAWATARI, Yo TANAKA, Yasuhiko SUGII, and Takehiko KITAMORIAnalytical Sciences, 27(12), 1173(2011)(selected as Hot Articles and Cover illustration)Optical Near-field Induced Visible Response Photoelectrochemical Water Splitting on Nanorod TiO2T. H. H. Le, K. Mawatari, Y. Pihosh, T. Kawazoe, T. Yatsui, M. Ohtsu, M. Tosa, T. KitamoriApplied Physics Letters, 99, 213105(2011)(selected in Virtual Journal of Nanoscale Science & Technology)Development of a Measurement Technique for Ion Distribution in an Extended Nanochannel by Super-Resolution-Laser-Induced FluorescenceYutaka Kazoe, Kazuma Mawatari, Yasuhiko Sugii, Takehiko KitamoriAnalytical Chemistry, 83(21), 8152-8157 (2011)Basic Structure and Cell Culture Condition of a Bioartificial Renal Tubule on Chip Towards a Cell based Separation MicrodeviceXiaofang GAO, Yo TANAKA, Yasuhiko SUGII, Kazuma MAWATARI, and Takehiko KITAMORIAnalytical Sciences, 27(9), 907(2011)Thermal lens detection deviceKazuma Mawatari, Toshinori Ohashi,b Tomohiko Ebata, Manabu Tokeshi,Takehiko KitamoriLab on a chip, 11, 2990-2993 (2011)Establishment of a confluent cardiomyocyte culture in a cylindrical microchannelYo Tanaka, Hiroto Akaike, Yasuhiko Sugii, Takehiko KitamoriAnalytical Sciences, 27(9), 957-960 (2011)In situ assembly, regeneration and plasmonic immunosensing of a Au nanorod monolayer in a closed-surface flow channelLonghua Guo, Youju Huang, Yoshikuni Kikutani, Yo Tanaka, Takehiko Kitamori, Dong-Hwan KimLab on a Chip, 11(19), 3299-3304 (2011)Shift of Isoelectric Point in Extended Nanospace Investigated by Streaming Current MeasurementK. Morikawa, K. Mawatari, Y. Kazoe, T. Tsukahara, T. KitamoriApplied Physics Letters, 99, 123115 (2011)Experimental investigation of droplet acceleration and collision in the gas phase in a microchannelKatsuyoshi Takahashi, Yasuhiko Sugii, Kazuma Mawatari and Takehiko KitamoriLab on a chip, 11 (18), 3098 &＃8211; 3105 (2011)Microfludic extraction of cupper from particle-laden solutionsC.Priest, J.Zhou, R.Sedev, J.Ralston, A.Aota, K.Mawatari, T.KitamoriInternational Journal of Mineral Processing, 98, 168-173 (2011)Sensitive Gas Analysis System on a Microchip and Application for on-site Monitoring of NH3 in a Clean RoomS. Hiki, K. Mawatari, A. Aota, M. Saito, T. KitamoriAnalytical Chemistry, 83 (12), 5017-5022 (2011)Rapid screening swine foot-and-mouth disease virus using micro-ELISA systemY. Dong, Y.Xu, Z. Liu, Y. Fu, T. Ohashi, Y. Tanaka, K. Mawatari, T.KitamoriLab on a Chip, 11, 2153-2155 (2011)Fluid actuation for a bio-micropump powered by previously frozen cardiomyocytes directly seeded on a diagonally stretched thin membraneYo Tanaka, Yuka Yanagisawa, Takehiko KitamoriSensors and Actuators B, 156(1), 494-498 (2011)(Published on the web: 27th April 2011)Single-Molecule DNA Patterning and Detection by Padlock Probing and Rolling Circle Amplification in Microchannels for Analysis of Small Sample VolumesYo Tanaka, Hui Xi, Kae Sato, Kazuma Mawatari, Bjorn Renberg, Mats Nilsson, Takehiko KitamoriAnalytical Chemistry, 83(9), 3352-3357(2011)(Published on the web: 4th April 2011)Cultivation and recovery of vascular endothelial cells in microchannels of a separable micro-chemical chipTadahiro Yamashita, Yo Tanaka, Naokazu Idota, Kae Sato, Kazuma Mawatari, and Takehiko KitamoriBiomaterials, 32, 2459-2465(2011).2010Experimental and Theoretical Characterization of an AC Electroosmotic MicromixerNaoki Sasaki, Takehiko Kitamori, Haeng-Boo KimAnalytical Sciences, 26(7), 815-819 (2010)Artificial chaperone-assisted refolding in a microchannelEtsushi Yamamoto, Satoshi Yamaguchi, Naoki Sasaki, Haeng-Boo Kim, Takehiko Kitamori, Teruyuki NagamuneBioprocess and Biosystems Engineering, 33(1), 171-177 (2010)Single-cell attachment and culture method using a photochemical reaction in a closed microfluidic systemKihoon Jang, Yan Xu, Yo Tanaka, Kae Sato, Kazuma Mawatari, Tomohiro Konno, Kazuhiko Ishihara, and Takehiko KitamoriBiomicrofluidics, 4(3), 032208(2010).On-chip antibody immobilization for on-demand and rapid immunoassay on a microfluidic chipToshinori Ohashi, Kazuma Mawatari, and Takehiko KitamoriBiomicrofluidics, 4(3), 032207(2010).The biological performance of cell-containing phospholipid polymer hydrogels in bulk and microscale formYan Xu, Kihoon Jang, Tomohiro Konno, Kazuhiko Ishihara, Kazuma Mawatari, and Takehiko KitamoriBiomaterials, 31, 8839-8846(2010).Development of a micro droplet collider; the liquid-liquid system utilizing the spatial-temporal localized energyKatsuyoshi Takahashi, Kazuma Mawatari, Yasuhiko Sugii, Akihide Hibara, and Takehiko KitamoriMicrofluidics and Nanofluidics, 9(4&＃8211;5), 945-953 (2010).Two-Step Perpendicular Free-Solution Isoelectric Focusing in a Microchamber Array ChipRyo Ishibashi, Takehiko Kitamori, and Kiyohito ShimuraLab on a Chip, 10, 2628-2631 (2010).Sensitive Determination of Concentration of Nonfluorescent Species in an Extended-nano Channel by Differential Interference Contrast Thermal Lens MicroscopeHisashi Shimizu, Kazuma Mawatari, and Takehiko KitamoriAnalytical Chemistry, 82(17), 7479-7484 (2010).A Microfluidic Hydrogel Capable of Cell Preservation Without Perfusion Culture Under Cell-based Assay ConditionsYan Xu, Kae Sato, Kazuma Mawatari, Tomohiro Konno, Kihoon Jang, Kazuhiko Ishihara, and Takehiko KitamoriAdvanced Materials, 22, 3017-3021 (2010) (Highlighted on the front inside cover of the journal).An efficient surface modification using 2-methacryloyloxyethyl phosphorylcholine to control cell attachment via photochemical reaction in a microchannelKihoon Jang, Kae Sato, Yo Tanaka, Yan Xu, Moritoshi Sato, Takahiro Nakajima, Kazuma Mawatari, Tomohiro Konno, Kazuhiko Ishihara, and Takehiko KitamoriLab on a chip, 10, 1937-1945 (2010).Microbead-based rolling circle amplification in a microchip for sensitive DNA detectionKae Sato, Atsuki Tachihara, Bjorn Renberg, Kazuma Mawatari, Kiichi Sato, Yuki Tanaka, Jonas Jarvius, Mats Nilsson, and Takehiko KitamoriLab on a Chip, 10, 1262-1266 (2010).Femto Liquid Chromatography with Attoliter Sample Separation in the Extended Nanospace ChannelMasaru Kato, Masanori Inaba, Takehiko Tsukahara, Kazuma Mawatari, Akihide Hibara, and Takehiko KitamoriAnalytycal Chemistry, 82(2), 543-547 (2010).Streaming potential/current measurement system for investigation of liquids confined in extended-nano spaceKyojiro Morikawa, Kazuma Mawatari, Masaru Kato, Takehiko Tsukahara, and Takehiko Kitamori.Lab on a Chip, 10(7), 871-875 (2010).Micro OS-ELISA: Rapid noncompetitive detection of a small biomarker peptide by open-sandwich ELISA integrated into microfluidic deviceM.Ihara, A.Yoshikawa, Y.Wu, H.Takahashi, K.Sato, K.Mawatari, T.Kitamori, and H.UedaLab on a Chip, 10, 92-100 (2010).2009Development of a Micro-Potentiometric Sensor for the Microchip Analysis of Alkali IonsAdelina SMIRNOVA, Kazuma MAWATARI, Hiroko TAKAHASHI, Yo TANAKA, Hiroaki NAKANISHI, and Takehiko KITAMORI.Analytical Sciences, 25(12), 1397-1402 (2009).Graft linker immobilization for spatial control of protein immobilization inside fused microchipsK. Shirai, B. Renberg, K. Sato, K. Mawatari, T. Konno, K. Ishihara, and T. Kitamori.Electrophoresis, 30(24), 4251-4255 (2009).Development of Differential Interference Contrast Thermal Lens Microscope (DIC-TLM) for Sensitive Individual Nanoparticle Detection in LiquidHisashi Shimizu, Kazuma Mawatari, and Takehiko KitamoriAnalytical Chemistry, 81(23), 9802-9806 (2009).Electrochemical Studies on Liquid Properties in Extended Nanospaces Using Mercury MicroelectrodesTakehiko Tsukahara, Takuya Kuwahata, Akihide Hibara, Haeng-Boo Kim, Kazuma Mawatari, and Takehiko KitamoriElectrophoresis, 30(18), 3212 &＃8211; 3218 (2009).Assembly and simple demonstration of a micropump installing PDMS-based thin membranes as flexible micro check valvesYo Tanaka, Kae Sato, and Takehiko KitamoriJournal of Biomedical Nanotechnology, 5(5), 516-520 (2009).The Direct Synthesis of Hydrogen Peroxide (ca. 5wt%) from Hydrogen and Oxygen by Microreactor TechnologyTomoya Inoue, Kenichiro Ohtaki,Yoshikuni Kikutani, Koichi Sato, Masateru Nishioka, Satoshi Hamakawa, Kazuma Mawatari, Fujio Mizukami, and Takehiko KitamoriChemistry Letters, 38, 820-821 (2009).Serial DNA immobilization in micro- and extended nanospace channelsBjorn Renberg, Kae Sato, Kazuma Mawatari, Naokazu Idota, Takehiko Tsukahara, and Takehiko KitamoriLab on a Chip, 9, 1517-1523 (2009).Hands on: thermal bonding of nano- and microfluidic chipsBjorn Renberg, Kae Sato, Takehiko Tsukahara, Kazuma Mawatari, and Takehiko KitamoriMicrochim Acta, 166, 177-181 (2009).NMR Studies of Structure and Dynamics of Liquid Molecules Confined in Extended NanospacesTakehiko Tsukahara, Wataru Mizutani, Kazuma Mawatari, and Takehiko KitamoriJ. Phys. Chem. B, 113, 10808-10816 (2009).Lateral spatial resolution of thermal lens microscopy during continuous scanning for nonstaining biofilm imagingT. T. J. Rossteuscher, A. Hibara, K. Mawatari, and T. KitamoriJournal of Applied Physics, 105, 102030 (2009).A Micro-ELISA System for the Rapid and Sensitive Measurement of Total and Specific Immunoglobulin E and Clinical Application to Allergy DiagnosisToshinori Ohashi, Kazuma Mawatari, Kae Sato, Manabu Tokeshi, Takehiko KitamoriLab on a Chip, 9, 991-995 (2009).Integration of immunoassay into extended nanospaceRyu Kojima, Kazuma Mawatari, Bjorn Renberg, Takehiko Tsukahara and Takehiko KitamoriMicrochimica Acta, 164, 307-310 (2009).(Published on the web: 28th June 2008)Circulation microchannel for liquid-liquid microextractionYoshikuni Kikutani, Kazuma Mawatari, Akihide Hibara and Takehiko KitamoriMicrochimica Acta, 164, 241-247 (2009).(Published on the web: 22nd May 2008)Phase separation of gas-liquid and liquid-liquid microflows in microchipsArata Aota, Kazuma Mawatari, Susumu Takahashi, Teruki Matsumoto, Kazuteru Kanda, Ryo Anraku, Akihide Hibara, Manabu Tokeshi and Takehiko KitamoriMicrochimica Acta, 164, 249-255 (2009).(Published on the web: 11th November 2008)The use of electron beam lithographic graft-polymerization on thermoresponsive polymers for regulating the directionality of cell attachment and detachmentNaokazu Idota, Takahiko Tsukahara, Kae Sato, Teruo Okano, Takehiko KitamoriBiomaterials, 30, 2095-2101 (2009).Individual Nanoparticle Detection in Liquids by Thermal Lens Microscopy and Improvement of Detection Efficiency Using a 1-µM Microfluidic ChannelNobuhiro SETA, Kazuma MAWATARI, and Takehiko KITAMORIAnalytical Sciences, 25(2), 275-278 (2009).Rapid analysis of methamphetamine in hair by micropulverized extraction and microchip-based competitive ELISAHajime Miyaguchi, Hiroko Takahashi, Toshinori Ohashi, Kazuma Mawatari, Yuko T. Iwata, Hiroyuki Inoue, Takehiko KitamoriForensic Science International, 184, 1-5 (2009).Surface Modification by 2-Methacryloyloxyethyl Phosphorylcholine Coupled to a Photolabile linker for Cell MicropatterningKihoon Jang, Kae Sato, Kazuma Mawatari, Tomohiro Konno, Kazuhiko Ishihara, and Takehiko KitamoriBiomaterials, 30, 1413-1420 (2009).2008Numerical analysis of thermal lens effect for sensitive detection on microchipRyo Anraku, Kazuma Mawatari, Manabu Tokeshi, Masatoshi Nara, Takahiro Asai, Akihiko Hattori, Takehiko KitamoriElectrophoresis, 29(9), 1895-1901 (2008).(Published on the web: 7th April 2008)Development of a pressure-driven nanofluidic control system and its application to an enzymatic reactionTakehiko Tsukahara, Kazuma Mawatari, Akihide Hibara, Takehiko KitamoriAnalytical and Bioanalytical Chemistry, 391(8), 2745-2752 (2008).(Published on the web: 27th June 2008)Circular Dichroism Thermal Lens Microscope in UV Wavelength Region (UV-CD-TLM) for Chiral Analysis on MicrochipKazuma Mawatari, Shun Kubota, Takehiko KitamoriAnalytical and Bioanalytical Chemistry, 391(7), 2521-2526 (2008).(Published on the web: 5th April 2008)Thermooptical detection in microships: From macro- to micro-scale with enhanced analytical parametersAdelina Smirnova, Mikhail A. Proskurnin, Svetlana N. Bendrysheva, Dmitry A. Nedosekin, Akihide Hibara and Takehiko KitamoriElectrophoresis, 29, 2741-2753 (2008).(Published on the web: 10th June 2008)Microfluidic Distillation Utilizing Micro-Nano Combined StructureAkihide Hibara, Kunihiko Toshin, Takehiko Tsukahara, Kazuma Mawatari and Takehiko KitamoriChemistry Letters, 37(10), 1064-1065 (2008).(Published on the web: 13th September 2008)Flowing thermal lens micro-flow velocimeterYoshikuni Kikutani, Kazuma Mawatari, Kenji Katayama, Manabu Tokeshi, Takashi Fukuzawa, Mitsuo Kitaoka and Takehiko KitamoriSensors and Actuators B: Chemical, 133, 91-96 (2008).(Published on the web: 9th February 2008)Pesticide analysis by MEKC on a microchip with hydrodynamic injection from organic extractAdelina Smirnova, Kiyohito Shimura, Akihide Hibara, Mikhail A. Proskurnin, Takehiko KitamoriJournal of Separation Science, 31, 904-908 (2008).(Published on the web: 25th February 2008)Isoelectric focusing in a microfluidically defined electrophoresis channelKiyohito Shimura, Katsuyoshi Takahashi, Yutaka Koyama, Kae Sato, Takehiko KitamoriAnalytical Chemistry, 80(10), 3818-3823 (2008).(Published on the web: 12th April 2008)Development of an osteoblast-based 3D continuous-perfusion microfluidic system for drug screeningKihoon Jang, Kae Sato, Kazuyo Igawa, Ung-il Chung, Takehiko KitamoriAnalytical and Bioanalytical Chemistry, 390(3), 825-832 (2008).(Published on the web: 15th December 2007)Micro- and nanometer-scale patterned surface in a microchannel for cell culture in microfluidic devicesMakiko Goto, Takehiko Tsukahara, Kiichi Sato, Takehiko KitamoriAnalytical and Bioanalytical Chemistry, 390(3), 817-823 (2008).(Published on the web: 26th July 2007)Demonstration of a bio-microactuator powered by vascular smooth muscle cells coupled to polymer micropillarsYo Tanaka, Kae Sato, Tatsuya Shimizu, Masayuki Yamato, Teruo Okano, Ichiro Manabe, Ryozo Nagai, and Takehiko KitamoriLab on a Chip, 8(1), 58-61 (2008).(Published on the web: 22nd November 2007)2007In situ microfluidic flow rate measurement based on near-field heterodyne grating methodKenji Katayama, Uchimura Hisato, Hitomi Sakakibara, Yoshikuni Kikutani, Takehiko KitamoriReview of Scientific Instruments, 78(8), 083101 (2007).(Published on the web: 13th August 2008)Simulation Examination for Multilayer Flow SystemRyo Anraku, Takahiro Asai, Kenji Uchiyama, Akihiko Hattori, Manabu Tokeshi, Takehiko KitamoriIFMBE Proceedings, 14(5), 318-320 (2007).Flow Velocity Detector in a Microchip Based on Photothermally Induced GratingKenji KATAYAMA, Yoshikuni KIKUTANI, and Takehiko KITAMORIAnalytical Sciences, 23(6), 639-643 (2007).On-Chip Connector Valve for Immunoaffinity Chromatography in a Microfluidic ChipK. Shimura, Y. Koyama, K. Sato, and T. KitamoriJ. Separation Science, 30(10), 1477-1481 (2007).Pressure Balance at the Liquid-Liquid Interface in Micro Counter-Current Flows in MicrochipsArata Aota, Akihide Hibara, Takehiko KitamoriAnalytical Chemistry, 79(10), 3919-3924 (2007)(Published on the web: 18th April, 2007)Tuning microchannel wettability and fabrication of multiple-step Laplace valvesGo Takei, Mari Nonogi, Akihide Hibara, Takehiko Kitamori and Haeng-Boo KimLab on a Chip, 7(5), 596-602 (2007).(Published on the web: 13th April, 2007)Development of an NMR Interface Microchip &＃8220;MICCS&＃8221;・for Direct Detection of Reaction Products and Intermediates of Micro-syntheses Using a &＃8220;MICCS-NMR&＃8221;Y. Takahashi, M. Nakakoshi, S. Sakurai, Y. Akiyama, H. Suematsu, H. UtsumiI, and T. KitamoriAnalytical Sciences, 23(4), 395-400 (2007).(Published on the web: 10th April, 2007)Rapid bonding of Pyrex glass microchipsYoshitaka Akiyama, Keisuke Morishima, Atsuna Kogi, Yoshikuni Kikutani, Manabu Tokeshi, Takehiko KitamoriElectrophoresis, 28(6), 994-1001 (2007).Highly Sensitive Detection of Non-Labeled Peptides Using UV Excitation Thermal Lens Microscope/Liquid ChromatographyShinichiro Hiki, Manabu Tokeshi, Masaya Kakuta, Kazuma Mawatari, Yoshikuni Kikutani, Kiichi Sato, Akihide Hibara, Kiyohito Shimura, Naoyuki Uchida and Takehiko KitamoriBunseki Kagaku, 56(1), 1-8 (2007).(Published on the web: 10th January, 2007)Nanometer-scale Patterned Surfaces for Control of Cell AdhesionMakiko Goto, Takehiko Tsukahara, Kae Sato, Tomohiro Konno, Kazuhiko Ishihara, Kiichi Sato, Takehiko KitamoriAnalytical Sciences, 23(3), 245-247.(Published on the web: 10th March, 2007)Culture and leukocyte adhesion assay of human arterial endothelial cells in a glass microchipYo Tanaka, Yuji Kikukawa, Kae Sato, Yasuhiko Sugii, Takehiko KitamoriAnalytical Sciences, 23(3), 261-266 (2007).(Published on the web: 10th March, 2007)Flow Velocity Profile of Micro Counter-Current FlowsArata Aota, Akihide Hibara, Kyosuke Shinohara, Yasuhiko Sugii, Koji Okamoto, Takehiko KitamoriAnalytical Sciences, 23(2), 131-133 (2007).(Published on the web: 10th February, 2007)NMR Study of Water Molecules Confined in Extended-Nano SpacesTakehiko Tsukahara, Akihide Hibara, Yasuhisa Ikeda, Takehiko KitamoriAngewandte Chemie International Edition, 46(7) 1180-1183 (2007) (Highlighted in the inside cover).(Published on the web: 29th January, 2007)Application of a micro multiphase laminar flow on a microchip for extraction and determination of derivatized carbamate pesticidesAdelina Smirnova, Kiyohito Shimura, Akihide Hibara, Mikhail A. Proskurnin, Takehiko KitamoriAnalytical Sciences, 23(1), 103-107 (2007).(Published on the web: 10th January, 2007)A micro-spherical heart pump powered by cultured cardiomyocytesYo Tanaka, Kae Sato, Tatsuya Shimizu, Masayuki Yamato, Teruo Okano, Takehiko KitamoriLab on a Chip, 7(2), 207-212 (2007).(Published on the web: 13th November, 2006)Countercurrent Laminar Microflow for Highly Efficient Solvent ExtractionArata Aota, Masaki Nonaka, Akihide Hibara, Takehiko KitamoriAngewandte Chemie International Edition, 46(6), 878-880 (2007).(Published on the web: 20th December, 2006)Simulation of photoacoustic imaging of microcracks in silicon wafers using a structure-changeable multilayered thermal diffusion modelNakata T, Kitamori T, SawadaApplied Optics, 46(7), 1019-1025 (2007).(Published on the web: 12th February, 2007)2006Instantaneous carbon-carbon bond formation using a microchannel reactor with a catalytic membraneYasuhiro Uozumi, Yoichi M. A. Yamada, Tomohiko Beppu, Naoshi Fukuyama, Masaharu Ueno, and Takehiko KitamoriJ. Am. Chem. Soc., 128(50) 15994-15995 (2006).(Published on the web: 1st December, 2006)Evaluation of effects of shear stress on hepatocytes by a microchip-baesd systemYuki Tanaka, Masayuki Yamato, Teruo Okano, Takehiko Kitamori, Kiichi SatoMeas. Sci. Technol. 17, 3167-3170 (2006).(Published on the web: 26th October, 2006)Pressure-driven flow control system for nanofluidic chemical processEiichiro Tamaki, Akihide Hibara, Haeng-Boo Kim, Manabu Tokeshi, Takehiko KitamoriJ. Chromatography A. 1137(2), 256-262, (2006).Radiation Degradation of Microchemical Chips and Capillary Tubes by Gamma-Ray IrradiationH.Ikeda, M.Tokeshi, H.Hotokezaka, Y.Ikeda, and T. KitamoriTrans. At. Energy Soc. Japan, 5(3), 209-220 (2006)Total reflection X-ray fluorescence analysis with chemical microchipK. Tsuji, Y. Hanaoka, A. Hibara, M. Tokeshi, and T. KitamoriSpectrochimica Acta Part B-Atomic Spectroscopy, 61(4), 389-392 (2006)Microchip-based liquid-liquid extraction for gas-chromatography analysis of amphetamine-type stimulants in urineHajime Miyaguchi, Manabu Tokeshi, Yoshikuni Kikutani,Akihide Hibara, Hiroyuki Inoue, and Takehiko KitamoriJ. Chromatogr. A, 1129, 105-110 (2006)Supercooled micro flows and application for asymmetric synthesisS. Matsuoka, A. Hibara, M. Ueno, T. KitamoriLab on a Chip, 6(9), 1236-1238 (2006)(Published on the web: 13th July, 2006)Miniaturized thermal lens and fluorescence detection system for microchemical chipsM. Yamauchi, M. Tokeshi, J. Yamaguchi, T. Fukuzawa, A. Hattori, A. Hibara, T. KitamoriJ. Chromatogr. A, 1106(1-2), 89-93 (2006).Micro-multiphase laminar flows for the extraction and detection of carbaryl derivativeA. Smirnova, K. Mawatari, A. Hibara, M. A. Proskurnin and T. KitamoriAnalytica Chimica Acta, 558(1-2), 69-74 (2006).Demonstration of a PDMS-based bio-microactuator using cultured cardiomyocytes to drive polymer micropillarsY. Tanaka, K. Morishima, T. Shimizu, A. Kikuchi, M. Yamato, T. Okano, and T. KitamoriLab on a Chip, 6(2), 230-235 (2006).On-Line High-throughput ESIMS detection of a Reaction Product Using Synthesis and Extraction MicrochipsY. Takahashi, R. Sakai, K. Sakamoto, Y. Yoshida, M. Kitaoka and T. KitamoriJ. Mass Spectrom. Soc. Jpn., 54(1), 19-24 (2006).An actuated pump on-chip powered by cultured cardiomyocytesY. Tanaka, K. Morishima, T. Shimizu, A. Kikuchi, M. Yamato, T. Okano, and T. KitamoriLab on a Chip, 6(3), 362-368 (2006)(Published on the web: 25th January 2006)AC electroosmotic micromixer for chemical processing in a microchannelN. Sasaki, T. Kitamori, and H.-B. KimLab on a Chip, 6(4), 550-554 (2006).(Published on the web: 14th February 2006)Cell Culture and Life Support System for MicrobioReactor and BioassayY. Tanaka, K. Sato, M. Yamato, T. Okano, and T. KitamoriJournal of Chromatography A, 1111(2), 233-237 (2006).(Published on the web: 11th July 2005)Monitoring of intercellular messengers released from neuron networks cultured in a microchipKiichi Sato, Akiko Egami, Tamao Odake, Manabu Tokeshi, Makoto Aihara and Takehiko KitamoriJournal of Chromatography A, 1111(2), 228-232 (2006).(Published on the web: 26th July 2005)Demonstration of a bio-microactuator powered by cultured cardiomyocytes coupled to hydrogel micropillarsK. Morishima, Y. Tanaka, M. Ebara, T. Shimizu, A. Kikuchi, M. Yamato, T. Okano, and T. KitamoriSensors and Actuators B: Chemical, 119(1), 345-350 (2006).(Published on the web: 20th January 2006) UV-excitation thermal lens microscope for non-labeled and ultrasensitive detection of non-fluorescent moleculesS. Hiki, K. Mawatari, A. Hibara, M. Tokeshi, and T. KitamoriAnalytical Chemistry, 78(8), 2859-2863 (2006).(Published on the web: 10th March 2006) Circular Dichroism Thermal Lens Microscope for Sensitive Chiral Analysis on MicrochipM.Yamauchi, K.Mawatari, A.Hibara, M.Tokeshi, and T.KitamoriAnalytical Chemistry, 78(8), 2646-2650 (2006).(Published on the web: 10th March 2006) Quantitative Detection and Fixation of Single and Multiple Gold Nanoparticles on a Microfluidic Chip by Thermal Lens MicroscopeK.Mawatari, M.Tokeshi, and T.KitamoriAnalytical Sciences, 22(4), 781-784 (2006). Liquid Filling Method for Nanofluidic Channels Utilizing High Solubility of CO2E. Tamaki, A. Hibara, H. B. Kim, M. Tokeshi, T. Ooi, M. Nakao, and T KitamoriAnalytical Sciences, 22(4), 529-532 (2006).On-chip integration of affinity chromatography and isoelectric focusing for the analysis of post-translational modificationShimura K, Koyama Y, Kitamori TMolecular & Cellular Proteomics, 5(10), S311-S311 1128 Suppl. (2006).2005Micro thermal lens optical systemsM. Tokeshi, J. Yamaguchi, A. Hattori, T. KitamoriAnal. Chem., 77 (2), 626-630 (2005).(Published on the web: 8th December 2004)Tunable thermal lens spectrometry utilizing microchannel-assisted thermal lens spectrometryE. Tamaki, A. Hibara, M. Tokeshi, T. KitamoriLab on a Chip, 5(2), 129-131 (2005).(Published on the web: 6th January 2005)Optimization of An Interface Chip for Coupling Capillary Electrophoresis with Thermal Lens Microscopic DetectionK. Uchiyama, M. Tokeshi, Y. Kikutani, A. Hattori, T. KitamoriAnal. Sci., 21, 49-52 (2005).Surface Modification Method of Microchannels for Gas-Liquid Two Phase Flow in MicrochipsA. Hibara, S. Iwayama, S. Matsuoka, M. Ueno, Y. Kikutani, M. Tokeshi, T. KitamoriAnal. Chem., 77(3), 943-947 (2005).(Published on the web: 31st December 2004)Photocatalytic Redox-Combined Synthesis of L-Pipecolinic Acid with a Titania-modified Microchannel ChipG. Takei, T. Kitamori, H.-B. KimCatal. Commun., 6, 357-360 (2005)(Published on the web: 21st March 2005)Spectroelectrochemical detection using thermal lens microscopy with a glass-substrate microelectrode-microchannel chipH.-B. Kim, T. Hagino, N. Sasaki, N. Watanabe, and T. KitamoriJ. Electroanal. Chem., 577(1), 47-53 (2005)(Published on the web: 25th December 2004)Development of a Microchip-based Bioassay System Using Cultured CellsM. Goto, K, Sato, A. Murakami, M. Tokeshi, T. KitamoriAnal. Chem., 77(7), 2125-2131 (2005)(Published on the web: 24th February 2005)Uraniumu (UO22+) Retention Property of Degraded n-dodecane by Acidic Radiolysis in the Prex ProcessH. Ikeda, M. Tokeshi, T. KitamoriRadioisotopes., 54(2), (2005)Rapid proton diffusion in microfluidic devices by means of micro -LIF techniqueK. Shinohara, Y. Sugii, A. Hibara, M. Tokeshi, T. Kitamori, K. OkamotoExperiments in Fluids, 38(1), 117-122 (2005).(Published on the web: 30th November 2004)Effect of Korteweg stress in miscible liquid two-layer flow in a microfluidic deviceY. Sugii, K. Okamoto, A. Hibara, M. Tokeshi, T. KitamoriJ. Visualization, 8(2), 117-124 (2005).Grazing-Exit and Micro X-ray Fluorescence Analyses for Chemical MicrochipsK. Tsuji, T. Emoto, Y. Nishida, E. Tamaki, Y. Kikutani, A. Hibara and T. KitamoriAnalytical Sciences, 21(7), 799-803 (2005).UV and circular dichroism thermal lens microscope for integrated chemical systems and HPLC on microchipK. Mawatari and T. KitamoriProc. SPIE, 5953, 595303.Application of a gas-pressurized micro fluidic pump to mu TAS technologyY. Tomotsune, T. Kawakami, S. Tomatsuri, T. Noguchi, T. Ito, K. Tatenuma, M. Kitaoka, T. KitamoriBUNSEKI KAGAKU, 54(12), 1169-1174 (2005) in Japanese.Development of the innovative nuclide separation system for high-level radioactive waste using microchannel chip-extraction behavior of metal ions from aqueous phase to organic phase in microchannelH. Hotokezaka, M. Tokeshi, M. Harada, T. Kitamori, Y. IkedaProgress in Nuclear Energy, 47, 439-447 (2005).Continuous flow chemical processing on a microchip using microunit operations and a multiphase flow networkTokeshi M, Kitamori TProgress in Nuclear Energy, 47, 434-437 (2005).2004Drug Response Assay System in a Microchip Using Human Hepatoma CellsYuki Tanaka, Kiichi Sato, Masayuki Yamato, Teruo Okano, Takehiko KitamoriAnal. Sci., 20, 411-423 (2004).(No. 3, March, 2004)Micro Wet Analysis System Using Multi-Phase Laminar Flows in Three-Dimensional Microchannel NetworkYoshikuni Kikutani, Hideaki Hisamoto, Manabu Tokeshi and Takehiko KitamoriLab on a Chip, 4(4), 328-332 (2004).(Published on Web April 6 2004)Measurement of pH field of chemically reacting flow in microfluidic devices by laser-induced fluorecenceKyosuke Shinohara, Yasuhiko Sugii, Koji Okamoto, Haruki Madarame, Akihide Hibara, Manabu Tokeshi, Takehiko KitamoriMesurement Science and Technology, 15, 955-960 (2004).(Published 20 April 2004)A microfluidic device for conducting gas-liquid-solid hydrogenation reactionsJ. Kobayashi, Y. Mori, K. Okamoto, R. Akiyama, M. Ueno, T. Kitamori, S. KobayashiScience, 304(5675), 1305-1308 (2004).(Published 28 May 2004)Capillary-assembled microchip for universal integration of various chemical functions onto a single microfluidic deviceH. Hisamoto, Y. Nakashima, C. Kitamura, S. Funano, M. Yasuoka, K. Morishima, Y. Kikutani, T. Kitamori, S. TerabeAnal. Chem., 76(11): 3222-3228 (2004).(Published 1 June 2004)High-speed micro-PIV measurements of transient flow in microfluidic devicesK. Shinohara, Y. Sugii, A. Aota, A. Hibara, M. Tokeshi, T. Kitamori, K. OkamotoMesurement Science and Technology, 15, 1965-1970 ・・004).(Published 20 August 2004)Microchip-based enzyme-linked immunosorbent assay (microELISA) system with thermal lens detectionK. Sato, M. Yamanaka, T. Hagino, M. Tokeshi, H. Kimura, T. KitamoriLab on a Chip, 4(6), 570-575 (2004).Integration of an immunoassay system into a microchip for high-throughput assaySato K, Kitamori TJOURNAL OF NANOSCIENCE AND NANOTECHNOLOGY, 4(6), 575-579 (2004).2003Chemico-Functional Membrane for Integrated Chemical Processes on a MicrochipHideaki Hisamoto, Yuki Shimizu, Kenji Uchiyama, Manabu Tokeshi, Yoshikuni Kikutani, Akihide Hibara, and Takehiko KitamoriAnal. Chem., 75, 350-354 (2003).(No. 2, January 15, 2003, Published on Web 12/13/2002)An Interface Chip Connection between Capillary Electrophoresis and Thermal Lens MicroscopeKenji Uchiyama, Akihide Hibara, Kiichi Sato, Hideaki Hisamoto, Manabu Tokeshi, Takehiko KitamoriElectrophoresis, 24, 179-184 (2003).(No. 1-2, January 2003, Published on Web ?)Microchannel-Assisted Thermal-Lens Spectrometry for Microchip AnalysisEiichiro Tamaki, Akihide Hibara, Manabu Tokeshi, and Takehiko KitamoriJ. Chromatogr. A, 987, 197-204 (2003).(No. 1-2, February 14, Published on Web 11/20/2002)Optimisation of Thermal Lens Microscopic Measurements in a MicrochipMikhail A. Proskurnin, Maksim N. Slyadnev, Manabu Tokeshi and Takehiko KitamoriAnal. Chim. Acta, 480, 79-95 (2003).(Issue 1, March 17, 2003, Published on Web ?)Phase-transfer Alkylation Reactions Using MicroreactorsMasaharu Ueno, Hideaki Hisamoto, Takehiko Kitamori and Shu KobayashiChem. Comm., 936-937 (2003).(No. 8, April 3, Published on Web 03/27/2003) Development of a Desktop-sized Themal Lens MicroscopeShinichiro Hiki, Manabu Tokeshi, Akihide Hibara and Takehiko KitamoriBunseki Kagaku (in Japanese), 52, 569-574 (2003).(No. 8, August, 2003)Spectroscopic Analysis of Liquid / Liquid Interfaces in Multiphase MicroflowsAkihide Hibara, Masaki Nonaka, Manabu Tokeshi, Takehiko KitamoriJ. Am. Chem. Soc., 125, 14954-14955 (2003).(No. 49, December 10, Published on Web 11/15/2003)2002Microchip-Based Immunoassay System with Branching Multichannels for Simultaneous Determination of Interferon GammaKiichi Sato, Maho Yamanaka, Hiroko Takahashi, Manabu Tokeshi, Hiroko Kimura, and Takehiko KitamoriElectrophoresis, 23, 734-739 (2002).(No. 5 March 2002, Published on Web 03/07/2002)Single Cell Analysis by a Scanning Thermal Lens Microscope with a Microchip: Direct Monitoring of Cytochrome-c Distribution During Apoptosis ProcessEiichiro Tamaki, Kiichi Sato, Manabu Tokeshi, Kae Sato, Makoto Aihara, and Takehiko KitamoriAnal. Chem. 74, 1560-1564 (2002).(No. 7, April 1, 2002, Published on Web 02/21/2002)Continuous Flow Chemical Processing on a Microchip by Combining Micro Unit Operations and a Multiphase Flow NetworkManabu Tokeshi, Tomoko Minagawa, Kenji Uchiyama, Akihide Hibara, Kiichi Sato, Hideaki Hisamoto, and T. KitamoriAnal. Chem., 74, 1565-1571 (2002).(No. 7, April 1, 2002, Published on Web 02/21/2002)Stabilization of Liquid Interface and Control of Two-Phase Confluence and Separation in Glass Microchips by Utilizing Octadecylsilane Modification of MicrochannelsAkihide Hibara, Masaki Nonaka, Hideaki Hisamoto, Kenji Uchiyama, Yoshikuni Kikutani, Manabu Tokeshi, and Takehiko KitamoriAnal. Chem., 74, 1724-1728 (2002).(No. 7, April 1, 2002, Published on Web 02/16/2002)Three-Layer Flow Membrane System on a Microchip for Investigation of Molecular TransportMariana Surmeian, Maxim N. Sladnev, Hideaki Hisamoto, Akihide Hibara, Kenji Uchiyama, and Takehiko KitamoriAnal. Chem., 74, 2014-2020 (2002).(No. 9, May 1, 2002,Published on Web 03/22/2002)Nanochannels on a Fused-Silica Microchip and Liquid Properties Investigation by Time-Resolved Fluorescence MeasurementsAkihide Hibara, Takumi Saito, Haeng-Boo Kim, Manabu Tokeshi, Takeshi Ooi, Masayuki Nakao, and Takehiko KitamoriAnal. Chem., 74, 6170-6176 (2002).(No. 24, December 15, 2002, Published on Web 11/08/2002)Pile-Up Glass MicroreactorYoshikuni Kikutani, Akihide Hibara, Kenji Uchiyama, Hideaki Hisamoto, Manabu Tokeshi, Takehiko KitamoriLab on a Chip, 2, 193-196 (2002).(No. 4, December, 2002, Published on Web 11/04/2002)Glass Microchip with Three-Dimensional Microchannel Network for 2ﾃ・ Parallel SynthesisYoshikuni Kikutani, Takayuki Horiuchi, Kenji Uchiyama, Hideaki Hisamoto, Manabu Tokeshi, Takehiko KitamoriLab on a Chip, 2, 188-192 (2002).(No. 4, December, 2002, Published on Web 11/08/2002)2001Integrated Multilayer Flow System on a MicrochipAkihide Hibara, Manabu Tokeshi, Kenji Uchiyama, Hideaki Hisamoto, Takehiko KitamoriAnal. Sci., 17, 89-93 (2001).Determination of Carcinoembryonic Antigen in Human Sera by Integrated Bead-Bed Immunoassay in a Microchip for Cancer DiagnosisKiichi Sato, Manabu Tokeshi, Hiroko Kimura, and Takehiko KitamoriAnal. Chem., 73, 1213-1218 (2001).On-Chip Integration of Neutral Ionophore-Based Ion Pair Extraction ReactionHideaki Hisamoto, Takayuki Horiuchi, Manabu Tokeshi, Akihide Hibara, and Takehiko KitamoriAnal. Chem., 73, 1382-1386 (2001).Determination of Sub-Yoctomole Amounts of Non-Fluorescent Molecules Using a Thermal Lens Microscope: Sub-Single Molecule DeterminationManabu Tokeshi, Marika Uchida, Akihide Hibara, Tsuguo Sawada, Takehiko KitamoriAnal. Chem., 73, 2112-2116 (2001).Morphological Dependence of Radiative and Non-Radiative Relaxation Energy Balance in Photoexcited Arylether Dendrimers as Observed by Fluorescent and Thermal Lens SpectroscopiesYuki Wakabayashi, Manabu Tokeshi, Akihide Hibara, Dong-Lin Jiang, Takuzo Aida, Takehiko KitamoriJ. Phys. Chem. B, 105, 4441-4445 (2001).Optimization of the Optical-Scheme Design for Photothermal-Lens Microscopy in MicrochipsMikhail A. Proskurnin, Manabu Tokeshi, Maxim N. Slyadnev, Takehiko KitamoriAnal. Sci., 17, s454-s457 (2001).Distribution of Methyl Red on Water-Organic Liquid Interface in MicrochannelMariana Surmeian, A. Hibara, M. Slyadnev, K. Uchiyama, H. Hisamoto, T. KitamoriAnal. Lett., 34, 1421-1429 (2001).Photothermal Temperature Control of a Chemical Reaction on a Microchip Using an Infrared Diode LaserMaxim N. Slyadnev, Yuki Tanaka, Manabu Tokeshi, T. KitamoriAnal. Chem., 73, 4037-4044 (2001).Acceleration of Enzymatic Reaction in a MicrochipYuki Tanaka, Maxim N. Slyadnev, Kiichi Sato, Manabu Tokeshi, Haeng-Boo Kim, Takehiko KitamoriAnal. Sci., 17, 809-810 (2001).Integration of a Wet Analysis System on a Glass Chip: Determination of Co(II) as 2-Nitroso-1-Naphtol Chelates by Solvent extraction and Themal Lens MicroscopeTomoko Minagawa, Manabu Tokeshi, Takehiko KitamoriLab on a Chip, 1, 72-75 (2001).Use of a thermal lens microscope in integrated catecholamine determination on a microchipHussein M. Sorouraddin, Akihide Hibara, Takehiko KitamoriFresenius&＃8217; Journal of Analytical Chemistry, 371, 91-96 (2001).Assay of Spherical Cell Surface Molecules by Thermal Lens Microscopy and Its Application to Blood Cell SubstancesHiroko Kimura, Kazuya Sekiguchi, Takehiko Kitamori, Tsuguo Sawada, Masahiro MukaidaAnal. Chem., 73, 4333-4337 (2001).On-Chip Integration of Sequential Ion Sensing System Based on Intermittent Reagent Pumping and Formation of Two-Layer FlowHideaki Hisamoto, Takayuki Horiuchi, Kenji Uchiyama, Manabu Tokeshi, Akihide Hibara, and Takehiko KitamoriAnal. Chem., 73, 5551-5556 (2001).Application of Microchip Fabricated of Photosensitive Glass for Thermal Lens MicroscopyTakeshi Ito, Kenji Uchiyama, Seishiro Ohya and Takehiko KitamoriJpn. J. Appl. Phys., 40, 5469-5473 (2001).Fast and High Conversion Phase-Transfer Synthesis Exploiting Liquid/Liquid Interface Formed in Microchannel ChipHideaki Hisamoto, Takumi Saito, Manabu Tokeshi, Akihide Hibara, and Takehiko KitamoriChem. Comm., 2001(24), 2662-2663 (2001).Highly sensitive and direct detection DNA fragments using a laser-induced capillary vibration effectT. Odake, K. Tsunoda, T. Kitamori, T. SawadaAnal. Sci., 17, 95-98 (2001).2000Integration of an Immunosorbent Assay System: Analysis of Secretory Human Immunoglobulin A on Polystyrene Beads in a MicrochipKiichi Sato, Manabu Tokeshi, Tamao Odake, Hiroko Kimura, Takeshi Ooi, Masayuki Nakao, Takehiko KitamoriAnal. Chem., 72, 1144-1147 (2000).Integration of a Microextraction System on a Glass Chip: Ion-Pair Solvent Extraction on Fe(II) with 4,7-Diphenyl-1,10-phenanthrolinedisulfonic Acid and Tri-n-octylmethylammonium ChlorideManabu Tokeshi, Tomoko Minagawa, Takehiko KitamoriAnal. Chem, 72, 1711-1714 (2000).Sub-Single Molecule Determination of Non-Fluorescent Species by Scanning Thermal Lens Microscope and Its Application to Single CellTakehiko Kitamori, Marika Uchida, Akiko Egami, Kazuya Sekiguchi, Jinjian Zheng, Tsuguo Sawada, Manabu Tokeshi, Kiichi Sato, Hiroko KimuraSPIE,, 3922, 67-72 (2000).Imaging of Blood Antigen Distribution on Blood Cells by Thermal Lens MicroscopyHiroko Kimura, Kazuya Sekiguchi, Fumiko Nagao, Masahiro Mukaida, Takehiko Kitamori, Tsuguo SawadaSPIE,, 278-284 (2000). Chemiluminescence on a MicrochipXing-Zheng Wu, Mari Suzuki, Tsuguo Sawada, Takehiko KitamoriAnal. Sci., 16, 321-323 (2000).Molecular Transport between Two Phases in a MicrochannelKiyoshi Sato, Manabu Tokeshi, Tsuguo Sawada, Takehiko KitamoriAnal. Sci., 16, 455-456 (2000).Integration of a Microextraction System: Solvent Extraction of Co-2-Nitroso-5-dimethylaminophenol Complex on a MicrochipManabu Tokeshi, Tomoko Minagawa, Takehiko KitamoriJ. Chromatogr. A,, 894, 19-23 (2000).Non-Contact Photothermal Control of Enzyme Reaction on a Microchip by Using a Compact Diode LaserYuki Tanaka, Maxim N. Slyadnev, Akihide Hibara, Manabu Tokeshi, Takehiko KitamoriJ. Chromatogr. A, 894, 45-51 (2000).Thermal Lens MicroscopeKenji Uchiyama, Akihide Hibara, Hiroko Kimura, Tsuguo Sawada, Takehiko KitamoriJpn. J. Appl. Phys., 39, 5316-5322 (2000).Integrated FIA for the Determination of Ascorbic Acid and Dehydroascorbic Acid in a Microfabricated Glass-Channel by Thermal-Lens MicroscopyHussein M. Sorouraddin, Akihide Hibara, Mikhail A. Proskrunin, Takehiko KitamoriAnal. Sci., 16, 1033-1037 (2000).Detection and measurement of a single blood cell surface antigen by thermal lens microscopyKimura H, Nagao F, Kitamura A, Sekiguchi K, Kitamori T, Sawada TAnal. Biochem., 283, 27-32 (2000).Infrared Absorption Characteristics of Large-Sized Spherical Aryl-Ether DendrimersYuki Wakabayashi, Manabu Tokeshi, Akihide Hibara, Dong-Lin Jiang, Takuzo Aida, Takehiko KitamoriAnal. Sci. 16, 1323-1326 (2000).Effect of organic phase on dynamic and collective behavior of surfactants at liquid/liquid interfaces by a time-resolved quasi-elastic laser-scattering methodZH. Hang, T. Kitamori, T. Sawada, I TsuyumotoAnal. Sci., 16, 1199-1202 (2000).1999Ultrafast electron transport phenomena in highly excited gold filmsA. Hibara, T. Morishita, I. Tsuyumoto, T. Kitamori, T. SawadaJ. Luminescence, 83&＃8211;4, 33-36 (1999).Single- and countable-molecule detection of non-fluorescent molecules in liquid phaseM. Tokeshi, M. Uchida, K. Uchiyama, T. Sawada, T. KitamoriJ. Luminescence, 83&＃8211;4, 261-264 (1999).Long-term energy storage of dendrimersY. Wakabayashi, M. Tokeshi, DL. Jiang, T. Aida, T. KitamoriJ. Luminescence, 83&＃8211;4, 313-315 (1999).Analysis of serum proteins adsorbed to a hemodialysis membrane of hollowfiber type by thermal lens microscopyH. Kimura, H. Kojima, M. Mukaida, T. Kitamori, T. SawadaAnal. Sci., 15, 1101-1107 (1999).Miniaturized ultrathin slab gel electrophoresis with thermal lens microscope detection and its application to fast genetic diagnosisJJ. Zheng, T. Odake, T. Kitamori, T. SawadaAnal. Chem., 71, 5003-5008 (1999).Critical increment of Lewis blood group antigen in serum by cancer found by photothermal immunoassayH. Kimura, T. Kitamori, T. SawadaAnal. Biochem., 274, 98-103 (1999).Structural change of heavy water by laser-induced plasma generationH. Yui, M. Fujinami, T. Kitamori, T. SawadaChem. Phys. Lett., 308, 437-440 (1999).Direct measurements of femtosecond energy dissipation processes of hot electrons in a gold filmA. Hibara, T. Morishita, I. Tsuyumoto, A. Harata, T. Kitamori, T. SawadaJpn. J. Appl. Phys., 38 (1999) 2983-2987.Integration of flow injection analysis and zeptomole-level detection of the Fe(II)-o-phenanthroline complexK. Sato, M. Tokeshi, T. Kitamori, T. SawadaAnal. Sci., 15, 641-645 (1999).Sub-attomole molecule detection in a single biological cell in-vitro by thermal lens microscopyM. Harada, M. Shibata, T. Kitamori, T. SawadaAnal. Sci., 15, 647-650 (1999).Enhancement of stimulated Raman scattering in laser-induced plasma formation in solvent mixtureH. Yui, T. Kitamori, T. SawadaChem. Phys. Lett., 306, 325-329 (1999).Sub-zeptomole detection in a microfabricated glass channel by thermal-lens microscopyK. Sato, H. Kawanishi, M. Tokeshi, T. Kitamori, T. SawadaAnal. Sci., 15, 525-529 (1999).Observation of one process in a phase transfer catalytic reaction at a liquid liquid interface by using the quasi-elastic laser scattering methodY. Uchiyama, I. Tsuyumoto, T. Kitamori, T. SawadaJ. Phys. Chem. B, 103, 4663-4665 (1999).Spectroscopic analysis of stimulated Raman scattering in the early stage of laser-induced breakdown in waterH. Yui, Y. Yoneda, T. Kitamori, T. SawadaPhys. Rev. Lett., 82, 4110-4113 (1999).Fast slab gel electrophoretic separation of DNA fragments with a short migration distance using thermal lens microscopeJJ. Zheng, T. Odake, T. Kitamori, T. SawadaAnal. Sci., 15, 223-227 (1999).1998Multiple-Channel Fluorescence Detector Using Optical Fiber Delay Lines for Variable Observation Angle Fluorescence Spectroscopy under Normal Incidence ConditionvTakuya SHIMOSAKA, Takehiko KITAMORI and Tsuguo SAWADAAppl. Spectrosc., 52, 308-311 (1998).Photothermal Effect of Single Ultrafine Particle and Individual Counting in LiquidKazuma MAWATARI, Takohiko KITAMORI, and Tsuguo SAWADAAnal. Chem., 70(23), 5037-5041 (1998).Density and Viscosity at Liqiod-Liquid Interface Region Studied by Quasi-Elastic Laser Scattering MethodIsao TSUYUMOTO, Naohei NOGUCHI, Takehiko KITAMORI and Tsuguo SAWADAJ. Phys. Chem. B, 102(15), 2684-2687 (1998).Monitoring of Molecular Transport at Liquid-Liquid Interface of Chemical Oscillation System by Time-Resolved Quasi-Elastic Laser Scattering MethodSatoshi TAKAHASHI, Isao, TSUYUMOTO, Takehiko KITAMORI, Tsuguo SAWADAElectrochim. Acta, 44(1), 165-169 (1998).Observation of the Dynamic and Collective Behavior of Surfactant Molecules at a Water/Nitrobenzene Interface by a Time-Resolved Quasi-Elastic Laser-Scattering MethodZ.-H. ZHANG, Isao TSUYUMOTO, Takehiko KITAMORI, Tsuguo SAWADAJ. Phys. Chem. B, 102(50), 10284-10287 (1998).解説1986-1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2016 2017 2020 2021 2022In press2022Photothermal spectroscopy and micro/nanofluidicsHisashi Shimizu, Chihchen Chen, Yoshiyuki Tsuyama, Takehiko Tsukahara,and Takehiko KitamoriJournal of Applied Physics, 132, 060902 (2022)2021Review of ultrasensitive readout for micro-/nanofluidic devices by thermal lens microscopyChihchen Chen, Hisashi Shimizu, and Takehiko KitamoriJ. of Optical Microsystems, 1, 020901(13pp), (2021).2020Advances in Label-Free Detections for Nanofluidic Analytical DevicesThu Hac Huong Le, Hisashi Shimizu, Kyojiro MorikawaMicromachines, 11, 885(21pp), (2020).2017Extended-nano chromatographyHisashi Shimizu, Adelina Smirnova, Kazuma Mawatari, Takehiko KitamoriJournal of Chromatography A, 1490,11-20(2017)2015マイクロELISAによる患者の微量検体の分析法森絵美, 細谷弓子, 今井靖, 大橋俊則, 田澤英克, 馬渡和真, 森田啓行, 北森武彦分析化学, Vol.64, No.6,pp461-468（2015）流体流路の階層サイズ構造とバイオデバイスへの応用北森武彦, 馬渡和真, 嘉副裕応用物理, Vol.84, No.10,pp882-888（2015）NMR分光法で見る拡張ナノ空間内における水及び非水溶媒の分子構造とダイナミクス塚原剛彦, 森川響二朗, 馬渡和真, 北森武彦分析化学, Vol.64, No.4,pp261-271（2015）2014Extended-nanofluidics: Fundamental Technologies, Unique liquid properties, and Application in Novel Chemical and Bio Analysis Methods and Devices K.Mawatari, Y.Kazoe, Y.Pihosh, H.Simizu, T.KitamoriAnalytical Chemistry, 86(9) (cover),4068-4077(2014)Thermal Lens Microscopy as a Detector in Microdevices C.Cassano, K.Mawatari, T.Kitamkori, H.Fan,Electrophoresis, 35(16),2279-2291(2014)拡張ナノ空間を用いたaL-fL高機能分析デバイスの開発馬渡和真、北森武彦生体の科学, 65(2),127-132 (2014)2013拡張ナノ流路における流速分布計測法の開発嘉副裕、井関恵三、馬渡和真、北森武彦ナノ学会会報, 12(2013)2012分子とバルク空間を繋ぐ空間（拡張ナノ空間）における溶液物性・化学反応馬渡和真，北森武彦展望とトピックス（第72回分析化学討論会）, 17(2012)マイクロ・拡張ナノ流体システムと新規エネルギーデバイスへの応用馬渡和真，Le Hac Huong Thu，Pihosh Yuriy，北森武彦オプトロニクス, 31, 363(2012)Microchip-based cellular biochemical systems for practical applications and fundamental research: from microfluidics to nanofluidicsYan Xu, Kihoon Jang, Tadahiro Yamashita, Yo Tanaka, Kazuma Mawatari, Takehiko KitamoriAnalytical and Bioanalytical Chemistry, 402(1), 99-107(2012)2011マイクロガス分析システムの開発と大気超微量アンモニアへの応用比企伸一郎, 馬渡和真, 北森武彦ケミカルエンジニヤリング, 第57巻, 第7号, 26-32(2011)Microflow Systems for Chemical Synthesis and Analysis: Approaches to Full Integration of Chemical ProcessK. Mawatari, Y. Kazoe, A. Aota, T. Tsukahara, K. Sato, T. KitamoriJournal of Flow Chemistry , 1, 3-12(2011)熱レンズ顕微鏡を用いた非蛍光性生体試料の超高感度計測比企伸一郎, 清水久史, 馬渡和真, 北森武彦光学, 40(5), 208-215(2011)マイクロ・ナノ化学システム山本竜広、嘉副裕、馬渡和真、北森武彦有機合成化学協会誌, , 69, 526-533(2011) Extended nanospace chemical systems on a chip for new analytical technologyK.Mawatari, T.Tsukahara, T.KitamoriAnalyst, 136, 3051-3059(2011).2010Extended-nano Fluidic Systems for Analytical and Chemical TechnologiesKazuma Mawatari, Takehiko Tsukahara, Yasuhiko Sugii, and Takehiko KitamoriNanoscale, 2, 1588-1595 (2010).Integrated Extended-nano Chemical Systems on a ChipTakehiko Tsukahara, Kazuma Mawatari, and Takehiko KitamoriChemical Society Reviews, 39, 1000-1013(2010).2009Parallel Multiphase Microflows: Fundamental Physics, Stabilization Methods and Its ApplicationsArata Aota, Kazuma Mawatari, and Takehiko KitamoriLab on a Chip, 9, 2470-2476 (2009).Padlock/RCA法を用いた単一DNA検出法の展開佐藤香枝化学と工業, 62-10, 1070-1072 (2009).Integrated fluidic systems on a nanometer scale and the study on behavior of liquids in small confinementAkihide Hibara, Takehiko Tsukahara, Takehiko KitamoriJournal of Chromatography A, 1216, 673-683 (2009).(Published on the Web: December 9, 2008)Combining microchip and cell technology for the creation of novel biodevicesKae Sato, Yo Tanaka, Björn Renberg and Takehiko KitamoriAnalytical and Bioanalytical Chemistry, 393(1), 23-29 (2009).2008Microchip-based cell analysis and clinical diagnosis systemKae Sato, Kazuma Mawatari and Takehiko KitamoriLab Chip, 8(12), 1992-1998 (2008).拡張ナノ空間の物性と分析化学への応用塚原剛彦，馬渡和真，北森武彦ぶんせき，9月号，454-458 (2008)．細胞集積化マイクロ・ナノ化学チップ佐藤香枝，田中陽，北森武彦分子細胞治療，7(1)，3-9 (2008)．マイクロ多相流を利用する溶媒抽出法青田新, 北森武彦分析化学，57(4)，239-250 (2008)．2007フォトサーマル分光馬渡和真，北森武彦化学会レポート分析化学会ディビジョン(日本化学会) Biological cells on microchips: New technologies and applicationsYo Tanaka, Kae Sato, Tatsuya Shimizu, Masayuki Yamato, Teruo Okano, Takehiko KitamoriBiosensors and Bioelectronics, 23(4), 449-458 (2007).光熱変換分光法馬渡和真，北森武彦ぶんせき進歩総説，7月号，350-355 (2007). 2006Functional thermal lens microscopes for ultrasensitive analysis of non-fluorescent molecules and microchip chemistryTakehiko Kitamori and Kazuma MawatariProceedings of SPIE, 6343, 63430C (2006).Ultrasensitive detection of nonfluorescent molecules in microspaceTakehiko Kitamori and Kazuma MawatariSPIE Newsroom, DOI: 10.1117/2.1200612.0471, (2006). 界面のはかりかた光散乱および光熱変換現象を利用した液液界面のはかりかた火原彰秀，北森武彦ぶんせき，6月号，242-248 (2006)．マイクロ化学チップテクノロジーと原子力-再処理工程溶液分析への適用を目指して渡慶次学，池田泰久(東工大)，北森武彦日本原子力学会誌，48(1)，38-43 (2006)．微量分析のためのNMR用デバイスの開発塚原剛彦ぶんせき，2月号，82 (2006)．熱レンズ顕微鏡による非蛍光性分子の超高感度検出馬渡和真，北森武彦臨床検査，50(12) 2006年増刊号，1487-1499 (2006).2005Continuous-flow chemical processing in three-dimensional microchannel network for on-chip integration of multiple reactions in a combinatorial modeY. Kikutani, M. Ueno, H. Hisamoto, M. Tokeshi, T. KitamoriQsar & Combinatorial Science, 24(6), 742-757 (2005).マイクロ化学システム北森武彦表面技術，56(3), 126-131 (2005)．酸化チタン薄膜を集積化したマイクロチャネルチップを用いた光触媒反応竹井豪，北森武彦，金幸夫化学と工業，58(2)，147-149 s(2005)．集積化ガラスチップ渡慶次学，菊谷善国表面技術，56(3)，132-137 (2005)．液液マイクロ多相流火原彰秀，北森武彦混相流，19(1)，16-24 (2005)．マイクロチャネル内気液二相流を利用した化学プロセス渡慶次学，北森武彦混相流，19(1)，25-30 (2005)．マイクロ化学バイオチップ入門北森武彦，田中有希応用物理，74(5)，623-627 (2005)．マイクロバイオシステム佐藤香枝，佐藤記一，北森武彦ケミカルエンジニヤリング，50(5)，329-334 (2005)．マイクロ化学上野雅晴，火原彰秀，北森武彦表面科学，26(2)，74-81 (2005)．2004Micro-flow reaction systems for combinatorial synthesesY. Kikutani, T. KitamoriMacromolecular Rapid Communications, 25(1), 158-168 (2004).(2nd January 2004)Thermal lens microscopy and microchip chemistryT. Kitamori, M. Tokeshi, A. Hibara, K. SatoAnalytical Chemistry, 76(3), 52A-60A (2004).(1st February 2004)Takehiko Kitamori &＃8211; ProfileT. KitamoriLab on a Chip, 4(3), 23N-27N (2004).マイクロ空間を利用した化学―微小にするメリットとは?北森武彦, 上野雅晴化学，59(2)，66-67 (2004)．非蛍光物質の超高感度計測渡慶次学，馬渡和真，火原彰秀，北森武彦応用物理学会誌，73(6)，741-748 (2004)．プレパラートが工場に! 集積化マイクロ化学システムの現状と展望上野雅晴，北森武彦月刊マテリアルステージ，39(6)，107-117 (2004)．熱レンズ顕微鏡火原彰秀，北森武彦化学，59(8)，42-43 (2004)．単一分子計測法馬渡和真，渡慶次学，北森武彦ぶんせき，506-512 (2004)．熱レンズ顕微鏡馬渡和真，比企伸一郎，福澤隆，山口淳，服部明彦，渡慶次学，北森武彦光学，33(12)，708-714 (2004)．マイクロチップで細胞を健全に飼う田中有希，佐藤記一，北森武彦高分子，872-875 (2004)． 2003Integrated chemical systems on microchips for analysis and assay. Potential future, mobile high-performance detection system for chemical weaponsKikutani Y, Tokeshi M, Sato K, Kitamori TPure and Applied Chemistry, 74, 2299-2309 (2003).(No. 12, December 2002)Integration of Chemical and Biochemical Analysis Systems into a Glass MicrochipKiichi Sato, Akihide Hibara, Manabu Tokeshi, Hideaki Hisamoto and Takehiko KitamoriAnalytical Sciences, 19, 15-22 (2003).(No. 1, January 2003)Microchip-Based Chemical and Biochemical Analysis SystemsKiichi Sato, Akihide Hibara, Manabu Tokeshi, Hideaki Hisamoto and Takehiko KitamoriAdvanced Drug Delivery Reviews, 55, 379-391 (2003).(Issue 3, 24 February 2003, Available on Web 01/10/2003)Chemical Processing on Microchips for Analysis, Synthesis, and BioassayManabu Tokeshi, Yoshikuni Kikutani, Akihide Hibara, Kiichi Sato, Hideaki Hisamoto, Takehiko KitamoriElectrophoresis, 24, 3583-3594 (2003)ミクロ空間における分子輸送と溶媒抽出―マイクロ化学システムの鍵―久本秀明，渡慶次学，火原彰秀，北森武彦イオン交換学会誌，2003，14(1)，38-43．(2003年1月) マイクロ化学システム渡慶次学，火原彰秀，北森武彦計測と制御，42，29-32 (2003)．(2003年1月)化学・バイオプロセスと集積化したマイクロバイオ化学システム森島圭祐，北森武彦OHM，90(1), (2003)．(2003年1月)オンチップセパレーション火原彰秀，北森武彦バイオマテリアル―生体材料―，21(2)，120-126 (2003)．(2003年3月)チップ内マルチイオンセンシングを目指したセグメントフロー―多相流形成の基礎検討久本秀明，堀内隆之，火原彰秀，渡慶次学，北森武彦電気学会誌，123-E(4) 124-127 (2003)．(2003年4月)マイクロチップを用いる有機合成久本秀明，菊谷善国，北森武彦触媒，45(3)，252-256 (2003)．(2003年4月)マイクロチップ分析システム渡慶次学，北森武彦化学工業，56，44-50 (2003)．吉と出るか凶と出るか―マイクロ化に向かうラボとプラント―北森武彦日立プラント技報，23，(2003)．マイクロチップを用いたイムノアッセイシステム渡慶次学，佐藤記一，北森武彦バイオサイエンスとインダストリー，7，449-454 (2003)．世界と我が国のマイクロ化学プロセスの動向北森武彦化学装置，(2003)．マイクロ化学チップの研究開発動向北森武彦Hitachi Scientific Instrument News，1 (2003)．インテグレーテッド・ケミストリー―世界の動向とプロジェクトの戦略・展開―北森武彦ファインケミカル (2003年9月15日特集号)．マイクロチップ化学プロセスの基盤技術の構築渡慶次学ファインケミカル (2003年9月15日特集号)．マイクロ合成化学システムの構築菊谷善国ファインケミカル (2003年9月15日特集号)．マイクロ生化学分析システムの構築佐藤記一ファインケミカル (2003年9月15日特集号)．マイクロ膜化学システムの構築久本秀明ファインケミカル (2003年9月15日特集号)．マイクロ電気化学システムの構築金幸夫ファインケミカル (2003年9月15日特集号)．バイオマイクロシステムの開発森島圭祐ファインケミカル (2003年9月15日特集号)．メソ空間化学の研究火原彰秀ファインケミカル (2003年9月15日特集号)．マイクロチップ技術のバイオサイエンスへの応用佐藤記一，北森武彦蛋白質核酸酵素，11，1595-1601 (2003)．次世代集積化マイクロ化学システム渡慶次学，菊谷善国，北森武彦ケミカルエンジニアリング，49，6-12 (2003)．2002マイクロチップにおける検出法とマイクロ分析システム渡慶次学，久本秀明，北森武彦計装，45，21-24 (2002)．マイクロ化学システム ―化学実験はマイクロチップで渡慶次学化学と工業，55，121-124 (2002)．High-Speed Assay on the WayTakehiko Kitamori, Kiichi SatoLook Japan, 48(554), 30-31 (2002)．集積化ミクロ化学システム金幸夫，北森武彦マテリアルインテグレーション，15(2)，-，(2002)．化学システムのミクロ集積化とインテグレーテッドケミストリー北森武彦，菊谷善国未来材料，2(2)，18-25 (2002)．セナとサイトウ・キネンに学ぼう北森武彦JAIMA SEASON，87，4-5 (2002)．コスト・時間・スペースをとらないミクロ実験室北森武彦ばんぶう，54-57 (2002)．マイクロチップ抽出場の創製からマイクロチップ化学へ渡慶次学，火原彰秀，久本秀明，北森武彦ぶんせき，(5)，257-262 (2002)．マイクロ化学チップ北森武彦，菊谷善国高圧ガス 39(4)，313 (2002)．マイクロ化学システム北森武彦現代化学，376，14-20 (2002)．「マイクロリアクタ設計工学」確立に向けて―現在の課題と今後―北森武彦，渡慶次学，菊谷善国化学装置，44，42-48 (2002)．マイクロ化学システム―集積化化学実験室―渡慶次学，北森武彦化学と教育，50，674-677 (2002)．マイクロチップイムノアッセイ北森武彦，渡慶次学，佐藤記一KAST Report，14，8-15 (2002)．分析システムのマイクロチップへの集積化佐藤記一，田中有希，北森武彦次世代センサ，12，(2002)．2001イムノアッセイマイクロチップの開発佐藤記一，木村博子，北森武彦バイオインダストリー，18，27-33 (2001)．マイクロチップ分析システムを用いた超微量物質の超高感度・高速分析渡慶次学，佐藤記一，木村博子, 北森武彦Biomedical Research on Trace Elements，12，85-90 (2001)．Integration Chemistry for Bio-chip: Integration of immunoassay and bio-chemical lab on a chipManabu Tokeshi, Kiichi Sato, and Takehiko KitamoriRIKEN Review，36, 24-25 (2001).熱レンズ顕微鏡火原彰秀，渡慶次学，北森武彦光技術コンタクト，449，20-27 (2001)．単一DNA分子によるスクリーニング ―PCRはもういらない渡慶次学化学と工業，54，819 (2001)．次世代の分析・計測技術 ―マイクロチップ分析システム―渡慶次学，内山堅慈，Maxim N. Slyadnev，菊谷善国機械振興，395，32-41 (2001)．化学反応場としてのマイクロ化学チップ ―マイクロ化学プラントへの技術と展望―金幸夫，久本秀明，佐藤記一，火原彰秀機械振興，395，42-49 (2001)．複合化学プロセスのマイクロチップ集積化火原彰秀，渡慶次学，北森武彦Electrochemistry (電気化学および工業物理化学)，69，620-623 (2001)．マイクロ分析システム佐藤記一，久本秀明，渡慶次学，木村博子，北森武彦BME，15(10)，24-30 (2001)．Miniaturization and chip technology in analytical chemistryTakehiko KitamoriFresenius&＃8217; Journal of Analytical Chemistry, 371(2), 89-90 (2001).Thermal lens microscope for integrated chemistry laboratory on glass microchipsAkihide Hibara, Kiichi Sato, Hideaki Hisamoto, Kenji Uchiyama, Maxim N. Slyadnev, Manabu Tokeshi, Takehiko KitamoriProgress in Natural Science, 11 Suppl., S237-S241 (2001).マイクロチップイムノアッセイシステム佐藤記一，北森武彦Molecular Electronics and Bioelectronics，12，217-226 (2001)．2000集積化したミクロ化学実験室 ―生体分子の検出と電気化学への期待―渡慶次学，北森武彦電気化学および工業物理化学，68，192-196 (2000)．化学実験装置をマイクロチップに集積化する技術のもたらすもの渡慶次学，北森武彦KAST Report，11，18-25 (2000)．免疫分析チップ佐藤記一，北森武彦Medical Technology，28，101-102 (2000)．イムノアッセイシステムのマイクロチップへの集積化佐藤記一，渡慶次学，木村博子，北森武彦生物物理化学，44，73-77 (2000)．熱レンズ顕微鏡による非蛍光生単一分子計測佐藤記一，渡慶次学，火原彰秀，北森武彦生物物理，230，262-265(2000)．インテグレーテッド・ケミストリー ―化学システムの集積化の現状―渡慶次学，北森武彦溶接学会誌，69，24-26 (2000)．一分子を測る火原彰秀，渡慶次学，北森武彦ぶんせき，591-596 (2000)．マイクロチップに集積化した化学システム―液相微小空間に期待する効果とは?―久本秀明，北森武彦ペトロテック，18，924-927 (2000)．1999レーザー誘起キャピラリー振動法によるDNA断片の高感度検出小竹玉緒，北森武彦精密工学会誌，181-185 (1999)．熱レンズ顕微鏡と非発光性分子の単一分子定量北森武彦蛋白質・核酸・酵素，44，1527-1531 (1999)．Ultrasensitive on-column detection of capillary electrophoresis using laser-induced capillary vibration methodTamao Odake, Takehiko Kitamori, Tsuguo SawadaANALUSIS, 26, M41 (1998).化学研究はマイクロチップの上で!北森武彦化学，54，14-19 (1999).1998化学実験の集積化とナノ流体輸送渡慶次学，北森武彦，澤田嗣郎化学，53，74-75 (1998)．分子一つを測る北森武彦化学と教育，46，228-229 (1998)．光熱変換分光法 ―生体関連物質の高感度分析への応用―小竹玉緒，北森武彦，澤田嗣郎現代化学，331，16-22 (1998)．熱レンズ顕微鏡北森武彦ぶんせき，847-853 (1998)． 1986-1997光音響分光法による液体試料の超高感度比色分析北森武彦，鈴木一道，澤田嗣郎，合志陽一The Hitachi Scientific Instruments News, 29, 1-4 (1986).光音響分光法による液中微粒子・超微粒子の分析澤田嗣郎，北森武彦表面，6，738-746 (1988)．クリーンルーム及びユーティリティのクリーン度評価斉木篤，三井泰裕，北森武彦，八掛保夫セミコンダクタ・ワールド，11，150-159 (1988)．光音響免疫分析法 -新たな超高感度免疫分析法-澤田嗣郎，北森武彦Bio-medica, 4, 41-46 (1989).光音響分光法による免疫分析北森武彦，澤田嗣郎Medical Technology, 17, 519-520 (1989).光音響効果を用いた免疫センサ澤田嗣郎，北森武彦センサ技術，9，75-78 (1989)．超微量分析の変革と展望 -超高感度光音響分光分析の新たな展開-北森武彦化学と工業，42，220-224 (1989)．光音響分光法による液中超微粒子計測北森武彦，澤田嗣郎日本原子力学会誌，31，558-559 (1989)．レーザブレイクダウン音響法による液中超微粒子計測坂上正治，北森武彦，澤田嗣郎高分子，38，366 (1989)．光音響分光法を用いた超高感度免疫分析北森武彦，澤田嗣郎高分子，38，427 (1989)．光音響分光法による懸濁試料の分析と免疫分析への応用北森武彦，坂上正治，澤田嗣郎The Hitachi Scientific Instruments News, 32, 9-12 (1989).光音響法による純水計測澤田嗣郎，北森武彦超音波テクノロジー，1，40-44 (1989)．液中超微粒子計測北森武彦，澤田嗣郎オプトロニクス，11，138-142 (1989)．光音響免疫分析法北森武彦，澤田嗣郎日本臨床，47，2818-2823 (1989)．レーザーブレイクダウン音響分光法による液中超微粒子計測北森武彦，澤田嗣郎化学工学，54，111-113 (1990)．超微量分析にみる「超」概念の変遷北森武彦，澤田嗣郎化学，46，179-181 (1991)．Novel Analytical and Chemometric Applications of Photothermal SpectroscopyTakehiko KITAMORI and Tsuguo SAWADASpectrochimica Acta Rev., 14, 275-302 (1991).ＰＵＲＥＸプロセスにおけるＮｐイオン分析技術のためのレーザー誘起光音響分光システムの開発木原武弘，藤根幸雄，前田　充，松井哲也，深沢哲夫，坂上正治，池田孝志，北森武彦JAERI-M レポート(日本原子力研究所)，91-142，1-53 (1991)．光熱変換効果を利用する超微量分析北森武彦，澤田嗣郎化学工業，43，113-120 (1992)．分析化学の科学北森武彦The Hitachi Scientific Instruments News, 35, 3616-3618 (1992).光で超薄膜内の分子挙動を探る北森武彦，澤田嗣郎化学，48，724-725 (1993)．光熱変換分光分析法北森武彦，澤田嗣郎ぶんせき，178-187 (1994)．化学反応の集積化北森武彦分光研究，43，176-177 (1994)．水の精製と計測北森武彦，斉藤恭一ぶんせき，808-812 (1994)．微量分析化学からみた高純度北森武彦化学工学，59，301-305 (1995)．レーザー分光法による生体成分の超微量分析北森武彦，澤田嗣郎ファルマシア(日本薬学会誌)，31，1138-1142 (1995)．光熱変換分光法の現状北森武彦超音波テクノ，7，12-17 (1995)．究極の超微量分析―検出限界に限界はあるか?―北森武彦化学，50，661-664 (1995)．検出限界北森武彦分担執筆ぶんせき，924-933 (1995)．高純度の世界と測定＜限りなく純粋に近い液体の分析技術＞北森武彦クリーンテクノロジー，23-26 (1996)．レーザー光熱変換分光法を用いる超微量免疫測定木村博子，北森武彦，澤田嗣郎ぶんせき，280-284 (1997)．分子を数える馬渡和真，佐藤清，北森武彦，澤田嗣郎日本機械学会誌，100，(1997)．書籍2003~ 1988-19972003~マイクロ・拡張ナノ化学デバイス森川響二朗、北森武彦2020版　薄膜作製応用ハンドブック, 第4編7章4節1項, p1428-1432, （株）エヌ・ティー・エス, (2020)震災後の工学は何をめざすのか第１章北森武彦東京大学大学院工学系研究科編, 内田老鶴圃,2012震災後の工学は何をめざすのか第６章第１節第６章第２節馬渡和真東京大学大学院工学系研究科編, 内田老鶴圃,2012マイクロ流体デバイスによる生体情報センシングおよび臨床検査分析馬渡和真、北森武彦先端バイオマテリアルハンドブック、（株）エヌ・ティー・エス, 2012Extended-nano Fluidic Systems for Chemistry and BiotechnologyK. Mawatari, T. Tsukahara, Y. Tanaka, Y. Kazoe, P. Dextras, T. KitamoriImperial College Press, 2011Micro- and NanofluidicsArata Aota, Takehiko Kitamoriin “Handbook of Nanofabrication” Ed. Stefano Cabrini and Satoshi Kawata, CRC / Taylor & Francis (2011), in pressMicro Unit Operations and Continuous Flow Chemical ProcessingArata Aota, Takehiko Kitamoriin “Micro Systems and Devices for (Bio)chemical Processes, Advances inChemical Engineering 38” Ed. Jaap C. Schouten, Academic Press (2010)研究室マネジメント入門人・資金・安全・知財・倫理1 研究室における人とお金のマネジメント北森武彦丸善株式会社(2009年4月23日発行)マイクロ・ナノ化学チップと医療・環境・バイオ分析第1編マイクロ化学チップ研究開発の現状と展望馬渡和真，北森武彦株式会社エヌ・ティー・エス(2009年1月23日発行)マイクロ・ナノ化学チップと医療・環境・バイオ分析第2編マイクロ化学チップの動作と原理第1章マイクロ化学チップの特性と動作性渡慶次学株式会社エヌ・ティー・エス(2009年1月23日発行)マイクロ・ナノ化学チップと医療・環境・バイオ分析第2編マイクロ化学チップの動作と原理第4章流体制御火原彰秀株式会社エヌ・ティー・エス(2009年1月23日発行)マイクロ・ナノ化学チップと医療・環境・バイオ分析第2編マイクロ化学チップの動作と原理第5章表面修飾金幸夫株式会社エヌ・ティー・エス(2009年1月23日発行)マイクロ・ナノ化学チップと医療・環境・バイオ分析第3編材料微細加工技術第5章ナノ加工塚原剛彦株式会社エヌ・ティー・エス(2009年1月23日発行)マイクロ・ナノ化学チップと医療・環境・バイオ分析第4編検出第1章レーザー・光検出馬渡和真株式会社エヌ・ティー・エス(2009年1月23日発行)マイクロ・ナノ化学チップと医療・環境・バイオ分析第5編応用技術第1章ナノテクノロジーを利用した超高性能DNA解析手法岡本行広，加地範匡，渡慶次学，馬場嘉信株式会社エヌ・ティー・エス(2009年1月23日発行)マイクロ・ナノ化学チップと医療・環境・バイオ分析第5編応用技術第2章マイクロ化学チップを用いたDNA増幅法佐藤香枝株式会社エヌ・ティー・エス(2009年1月23日発行)マイクロ・ナノ化学チップと医療・環境・バイオ分析第5編応用技術第3章生体分子固定化マイクロチップ加藤大株式会社エヌ・ティー・エス(2009年1月23日発行)マイクロ・ナノ化学チップと医療・環境・バイオ分析第5編応用技術第4章イムノアッセイ・バイオアッセイ佐藤記一株式会社エヌ・ティー・エス(2009年1月23日発行)マイクロ・ナノ化学チップと医療・環境・バイオ分析第5編応用技術第7章バイオマイクロアクチュエーター田中陽株式会社エヌ・ティー・エス(2009年1月23日発行)マイクロ・ナノ化学チップと医療・環境・バイオ分析第5編応用技術第9章多機能集積化学センシング久本秀明株式会社エヌ・ティー・エス(2009年1月23日発行)マイクロ・ナノ化学チップと医療・環境・バイオ分析第5編応用技術第17章拡張ナノ空間化学塚原剛彦株式会社エヌ・ティー・エス(2009年1月23日発行)マイクロ・ナノ化学チップと医療・環境・バイオ分析第6編企業のアプローチ第1章マイクロ免疫分析システム大橋俊則株式会社エヌ・ティー・エス(2009年1月23日発行)マイクロ・ナノ化学チップと医療・環境・バイオ分析第6編企業のアプローチ第3章大気中アンモニア分析八谷宏光株式会社エヌ・ティー・エス(2009年1月23日発行)分析システムの集積化馬渡和真，北森武彦新しい地平をひらく分析手法の最前線(化学フロンティア)，化学同人(2009年)Micro Total Analysis SystemYuki Tanaka, Takehiko Kitamoriin “Unconventional Nanopatterning Techniques and Applications.” Ed. J.A.Rogers, H.H.Lee, A John Wiley & Sons,Inc. (2009)Microchip ImmunoassaysKiichi Sato, Takehiko Kitamori“Handbook of Capillary And Microchip Electrophoresis And Associated Microtechniques” Ed. James P. Landers, CRC / Taylor & Francis (2008)Solvent Extraction on ChipsManabu Tokeshi, Takehiko Kitamori“Handbook of Capillary And Microchip Electrophoresis And Associated Microtechniques” Ed. James P. Landers, CRC / Taylor & Francis (2008)Flow Analysis in Microfluidic DevicesManabu Tokeshi, Takehiko Kitamoriin “Advances in Flow Analysis”Ed. M. Trojanowicz, Wiley & Sons,Inc. (2008)Detection using thermal lensingK.Mawatari and T.Kitamoriin “Encyclopedia of Micro- and Nanofluidics,” D. Li (Ed.), Springer-Verlag:Berlin Heidelberg, in press (2008).早わかりマイクロ化学チップ北森武彦丸善株式会社(2006年11月1日発行)．熱レンズ顕微鏡馬渡和真，北森武彦ナノバイオ大辞典(テクノシステム)，pp. 403-404 (2006)．マイクロ流体学火原彰秀，北森武彦ナノバイオ大辞典(テクノシステム)，pp. 545-546 (2006)．ミクロ相分離渡慶次学，北森武彦ナノバイオ大辞典(テクノシステム)，pp. 551-552 (2006).New Horizons in Nano- and Micro-BiotechnologyMeas. Sci. Technol., 17(12) (2006).Editorial; Takehiko Kitamori熱レンズ顕微鏡とマイクロ化学チップ分析システム馬渡和真，北森武彦光科学研究の最前線，pp. 306-307 (2005)マイクロリアクタテクノロジー～限りない可能性と課題～第2章 1. 集積化ハイスループットシステムとしてのマイクロ化学システムの構築北森武彦・菊谷善国株式会社エヌ・ティー・エス(2005年7月発行)マイクロリアクタテクノロジー～限りない可能性と課題～第4章 6. マイクロチップを用いた環境粒子計測宮村和宏・馬渡和真株式会社エヌ・ティー・エス(2005年7月発行)マイクロリアクタテクノロジー～限りない可能性と課題～第4章 13. 化学反応高度分析のためのマイクロ化学チップ―熱レンズ分光分析装置の開発―渡慶次学株式会社エヌ・ティー・エス(2005年7月発行)高分子材料・技術総覧第3編第5章第1節「バイオ・マイクロ化学チップ」田中有希・北森武彦(株)産業技術サービスセンター刊(2004年9月)第5章 1. ラボオンチップ総論火原彰秀，北森武彦バイオチップの最新技術と応用シーエムシー出版(2004年6月発行)第5章 2. バイオマイクロシステムの開発森島圭祐バイオチップの最新技術と応用シーエムシー出版(2004年6月発行)第5章 4. 電極集積化マイクロチャネルチップ金幸夫バイオチップの最新技術と応用シーエムシー出版(2004年6月発行)コンビナトリアルテクノロジー―明日を開く‘もの作り’の新世界―北森武彦・渡慶次学第2部マイクロケミカルテクノロジー第1章マイクロチップケミストリー丸善株式会社(2004年7月)マイクロ化学チップの技術と応用編者北森武彦，庄司習一，馬場嘉信，藤田博之執筆者上野雅晴，金幸夫，佐藤記一，渡慶次学，火原彰秀，森島圭祐化学とマイクロ・ナノシステム研究会(2004年9月)マイクロ流路による微小バイオテクノロジー渡慶次学，佐藤記一，北森武彦ナノバイオエンジニアリングマテリアルフロンティア出版(2004年3月発行)基礎化学コース分析化学III 超微量分析梅沢善夫，木村博子，角田欣一，北森武彦，下田満哉，馬場嘉信丸善株式会社(2004)第III部展望編 4. マイクロリアクタにおける触媒 catalysis for microreactor上野雅晴，北森武彦触媒活用大事典工業調査会(2004年発行)４章5節マイクロチップを用いる分析佐藤記一，北森武彦先端の分析法～理工学からナノ・バイオまで～エヌ・ティー・エス(2004年12月発行)第1章総論北森武彦インテグレーテッド・ケミストリーシーエムシー出版(2004年3月発行)第2章マイクロチップ化学プロセスの設計第3章超高感度検出器渡慶次学インテグレーテッド・ケミストリーシーエムシー出版(2004年3月発行)第5章マイクロ流体火原彰秀インテグレーテッド・ケミストリーシーエムシー出版(2004年3月発行)第6章マイクロ分析化学システム久本秀明，渡慶次学，佐藤記一インテグレーテッド・ケミストリーシーエムシー出版(2004年3月発行)第7章マイクロ化学合成システム菊谷善国インテグレーテッド・ケミストリーシーエムシー出版(2004年3月発行)第8章細胞実験システムの集積化佐藤記一，森島圭祐インテグレーテッド・ケミストリーシーエムシー出版(2004年3月発行)第9章マイクロ電気化学システムの構築金幸夫インテグレーテッド・ケミストリーシーエムシー出版(2004年3月発行)第10章マイクロ・メソ空間の物理化学火原彰秀インテグレーテッド・ケミストリーシーエムシー出版(2004年3月発行)マイクロ・バイオ化学システム北森武彦，火原彰秀ナノバイオテクノロジーの最前線シーエムシー出版(2003年10月発行)6.1 集積化マイクロ化学システム金幸夫，北森武彦，火原彰秀ナノテクノロジー大事典工業調査会(2003)次世代基盤技術ナノ・マイクロテクノロジー金幸夫，渡慶次学化学便覧応用化学編I 第6版，丸善株式会社(2003年)マイクロ・ナノスケールの化学北森武彦ナノテクノロジーハンドブックI編創る(第1分冊)オーム社，平成15年5月25日発行(2003年)マイクロ分析チップ渡慶次学ナノテクノロジーハンドブックIV編バイオ・化学へ使う(第4分冊)オーム社，平成15年5月25日発行(2003年)ナノ・マイクロテクノロジーと分析・計測技術金幸夫ナノテクノロジーハンドブックIV編バイオ・化学へ使う(第4分冊)オーム社，平成15年5月25日発行(2003年)マイクロバイオリアクター久本秀明ナノテクノロジーハンドブックIV編バイオ・化学へ使う(第4分冊)オーム社，平成15年5月25日発行(2003年)4節バイオデバイス 3. マイクロ化学デバイス佐藤記一，北森武彦21世紀版薄膜作製応用ハンドブック，エヌ・ティー・エス(2003年4月出版)基礎科学コース生命化学II 遺伝子の働きとその応用渡辺公綱，姫野俵太共著，井上晴夫，北森武彦，小宮山真，高木克彦，平野眞一編丸善株式会社(2003)Micro Chemical Processing on MicrochipsYoshikuni Kikutani, Takehiko KitamoriElectrokinetic Phonomena, 253-275 (2003)Micro Integrated Chemical Systems for General UseYoshikuni Kikutani, Akihide Hibara, Hideaki Hisamoto, Manabu Tokeshi, Takehiko KitamoriLab-on-a-Chip: Miniaturized Systems for (Bio)Chemical Analysis and Synthesis, Eds., R.E.Oosterbrock and A. van den Berg, Elsevier, (2003).1988-1997光熱変換分光法の基礎と応用北森武彦，共著学会出版センター，東京(1997)高純度化のための分析技術北森武彦，分担執筆「光音響分光法」「光熱変換分光法」フジテクノシステム，東京(1996)分析化学データブック北森武彦，分担執筆「光源(レーザー)」丸善，東京，122-124(1993)表面分析図鑑北森武彦，分担執筆「光音響分光法」丸善，東京，52-53 (1993)レーザー分光計測の基礎と応用北森武彦，分担執筆「レーザー散乱法」「微弱信号測定法」Industrial Publishing & Consulting，東京，301-326， 527-554 (1992)光センサ・テクノロジー集北森武彦，澤田嗣郎，分担執筆「粒径計測法」オプトロニクス社，東京，141-145 (1990)半導体プロセス・デバイス計測技術北森武彦，分担執筆「クリーン度の評価法」プレスジャーナル，東京，175-184 (1990)Physical Acoustics Vol. 18Tsuguo SAWADA and Takehiko KITAMORI&＃8220;Analytical Applications of Photoacoustic Spectroscopy to Condensed Phase&＃8221;Academic Press, New York, 347-401 (1988)特許等準備中です。 CONTENTS 研究内容教育社会連携・社会貢献メンバー論文・解説・書籍・特許等招待講演学会発表受賞・表彰等研究室内イベントリンク東京大学東京大学大学院工学系研究科マイクロ化学技研株式会社 CBMS 1998-2017 Kitamori Lab.All Rights Reserved.

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