- Folding Coupled with Assembly in Split Green Fluorescent Proteins
Studied by Structure-Based Molecular Simulations.
M. Ito, T. Ozawa and S. Takada,
J. Phys. Chem., in press.
- Bioluminescence as a Tool of Molecular Imaging.
S.B. Kim and T. Ozawa,
Curr. Mol. Imaging, in press.
- Sustained Accurate Recording of Intracellular Acidification in Living
Tissues with a Photo-controllable Bioluminescent Protein.
M. Hattori, S. Haga, H. Takakura, M. Ozaki and T. Ozawa,
Proc. Nat. Acad. Sci. USA, in press.
- Spatiotemporal visualization of proHB-EGF ectodomain shedding in living cells.
H. Inoue, T. Sakaue, T. Ozawa and S. Higashiyama,
J. Biochem., in press.
- Analysis of temporal patterns of GPCR–β-arrestin interactions using
split luciferase-fragment complementation.
M. Hattori, M. Tanaka, H. Takakura, K, Aoki, K. Miura, T. Anzai and T. Ozawa,
Mol. Biosystems,9, 957-964 (2013).
- Longitudinal Bioluminescence Imaging of the Dynamics of Doxorubicin Induced Apoptosis.
G. Niu, L. Zhu, D.N. Ho, F. Zhang, H. Gao, Q. Quan, N. Hida, T. Ozawa, G. Liu and X. Chen,
Theranostics, 3, 190-200 (2013).
- Rational Design and Development of Near-infrared-emitting FireflyLuciferins Available in vivo.
R. Kojima, H. Takakura, T. Ozawa, Y. Tada, T. Nagano and Y. Urano,
Angew. Chem. Int. Ed., 52,1175-1179 (2013).
- Advances in fluorescence and bioluminescence imaging
T. Ozawa, H. Yoshimura and S.B. Kim,
Anal. Chem., 85, 590-609 (2013).
- Intelligent Design of Nano-Scale Molecular Imaging Agents.
S.B. Kim, M. Hattori and T. Ozawa,
Int. J. Mol. Sci., 13, 16986-17005 (2012).
- Measuring CREB activation using bioluminescent probes that detect KID-KIX interaction in living cells.
T. Ishimoto, H. Mano, T. Ozawa and H. Mori
Bioconjugate Chem., 23, 923-932 (2012).
- Development of 5 and 7 Substituent Luciferin Analogues as an Acidic-Tolerant Substrate of Firefly Luciferase.
H. Takakura, R. Kojima, T. Ozawa, T. Nagano and Y. Urano
ChemBioChem,13, 1424-1427 (2012).
- Fluorescent probes for imaging endogenous β-actin mRNA in living
cells using fluorescent protein-tagged pumilio.
H. Yoshimura, A. Inaguma, T. Yamada and T. Ozawa
ACS Chem. Biol., 7, 999-1005 (2012).
- Visualization and Quantitative Analysis of G Protein-Coupled Receptor β-Arrestin
Interaction in Single Cells and Specific Organs of Living Mice Using Split Luciferase Complementation.
H. Takakura, M. Hattori, M. Takeuchi and T. Ozawa
ACS Chem. Biol.,7, 901-910 (2012).
- In vivo monitoring of liver damage using caspase-3 probe.
M. Ozaki, S. Haga and T. Ozawa,
Theranostics,2, 207-214 (2012).
- Synchronization of circadian Per2 rhythms and HSF1-BMAL1: CLOCK interaction in mouse fibroblasts after short-term heat shock pulse.
T. Tamaru, M. Hattori, K. Honda, I. Benjamin, T. Ozawa and K. Takamatsu,
PLoS ONE,6, e24521 (2011).
- Visualization of non-engineered single mRNAs in living cells using genetically encoded fluorescent probes.
T. Yamada, H. Yoshimura, A. Inaguma and T. Ozawa,
Anal. Chem., 83, 5708-5714 (2011).
- Real-time monitoring of actin polymerization in living cells using split luciferase.
T. Ishimoto, T. Ozawa and H. Mori,
Bioconjugate Chem., 22, 1136-1144 (2011).
- Illuminating Intracellular Signaling and Molecules for Single Cell Analysis
M. Awais and T. Ozawa
Mol. Biosystems, 7, 1376-1387 (2011).
- Imaging of Endogenous RNA Using Genetically-encoded Probes,
T. Ozawa and Y. Umezawa
Current Protocols in Chemical Biology, 3, 27-37 (2011).
- Genetically-Encoded Fluorescent Probes for Imaging Endogenous mRNA in Living Cells,
T. Ozawa and Y. Umezawa
Methods in Molecular Biology, 714, 175-188 (2011).
- Dual-Color Bioluminescence Analysis for Quantitatively Monitoring G-Protein-Coupled Receptor and b-Arrestin Interactions.
A.K.M. Kafi, M. Hattori, N. Misawa and T. Ozawa,
Pharmaceuticals, 4, 457-469 (2011).
- Detection of Protein-Protein Interactions in Bacteria by GFP-fragment Reconstitution,
A. Kanno, T. Ozawa and Y. Umezawa
Methods in Molecular Biology, 705, 251-258 (2011).
- Ratiometric Bioluminescence Indicators for Monitoring Cyclic AMP in Live Cells Based on Luciferase-Fragment Complementation.
Takeuchi M., Nagaoka Y., Yamada T., Takakura H. and Ozawa T.
Anal. Chem., 82, 9306-9313 (2010).
- Luciferases for the Study of Protein-Protein Interactions in Live Cells and Animals.
Kafi A.K.M., Hattori M., and Ozawa T.,
Nano Life, 1, 45-62 (2010).
- p66(Shc) has a Pivotal Function in Impaired Liver Regeneration in Aged Mice by a Redox-Dependent Mechanism.
Haga S., Morita N., Irani K., Fujiyoshi M., Ogino T., Ozawa T., and Ozaki M.,
Lab Invest., 90, 1718-1726 (2010)
- Creating Bioluminescent Indicators to Visualize Biological Events in Living Cells and Animals.
Kim S. B., and Ozawa T.,
Supramol. Chem., 22, 439-448 (2010).
- Rapid and High-Sensitivity Cell Based Assays of Protein−Protein Interactions Using Split Click Beetle Luciferase Complimentation: An Approach to the Study of G-Protein Coupled Receptors
Misawa N., Kafi A. K. M., Hattori M., Miura K., Masuda K., Ozawa T.,
Anal. Chem. ,82, 2552-2560 (2010).
- Bioluminescenct Imaging of MAPK function with intein-mediated reporter gene assay,
A. Kanno, T. Ozawa, and Y. Umezawa ,
Methods Mol. Biol., 574, 185–192 (2009).
- Detection of Apoptosis Using Cyclic Luciferase in Living Mammals,
A. Kanno, Y. Umezawa and T. Ozawa
Bioluminescence, Methods in Molecular Biology , 574, 105–114 (2009).
- Protein Reconstitution Methods for Visualizing Biomolecular Function in
Living Cells,
T. Ozawa,
YAKUGAKU ZASSHI, 129, 289–295 (2009).
- High-sensitivity real-time imaging of dual protein-protein interactions in living subjects using multicolor luciferases.
Hida N, Awais M, Takeuchi M, Ueno N, Tashiro M, Takagi C, Singh T, Hayashi M, Ohmiya Y, Ozawa T,
PLoS One, 4, e5868 (2009).
- Molecular Science for Analyzing Dynamics of Biomolecules in Living Cells,
T. Ozawa,
J. JSCAS., 10, 489–439 (2008).
- Cyclic Luciferase for Real-Time Sensing of Caspase-3 Activities in Living Mammals.
A. Kanno, Y. Yamanaka, H. Hirano, Y. Umezawa and T. Ozawa,
Angew. Chem. Int. Ed., 46, 7595–7599 (2007).
- Nongenomic Activity of Ligands in the Association of Androgen Receptor with Src.
S.B. Kim, A. Kanno, T. Ozawa, H. Tao and Y. Umezawa,
ACS Chem. Biol., 2, 484–492 (2007).
- Imaging Dynamics of Endogenous Mitochondrial RNA in Single Living Cells.
T. Ozawa, Y. Natori, M. Sato and Y. Umezawa,
Nature Methods, 4, 413–419 (2007).
- A Minimal Peptide Sequence That Targets Fluorescent and Functional Proteins into the Mitochondrial Intermembrane Space.
T. Ozawa, Y. Natori, Y. Sako, H. Kuroiwa, T. Kuroiwa and Y. Umezawa,
ACS. Chem. Biol., 2, 176–186 (2007).
- A Proinflammatory Cytokine Sensor Cell for Assaying Inflammatory Activities of Nanoparticles.
S.B. Kim, T. Ozawa, H. Tao and Y. Umezawa,
Anal. Biochem., 362,148–150 (2007).
- Methods for Imaging and Analyses of Intracellular Organelles Using Fluorescent and Luminescent Proteins.
M. Takeuchi and T. Ozawa,
Anal. Sci., 23, 25–29 (2007).
-
Genetic Nanomedicine and Tissue Engineering,
C. Wei, M. Yamoto, W. Wei, Z. Zhao, K. Tsumoto, T. Yoshimura, T. Ozawa and Y. J. Chen,
Med. Clin. North Am., 91, 889–898 (2007). -
Identification of Proteins Targeted into the Endoplasmic Reticulum by cDNA Library Screening,
T. Ozawa and Y. Umezawa,
Methods Mol. Biol., 390, 269–280 (2007).
- A Genetic Method to Identify Mitochondrial Proteins in Living Mammalian Cells,
T. Ozawa and Y. Umezawa,
Methods Mol. Biol., 390, 119–130, (2007).
- A Genetically Encoded Optical Probe for Detecting Release of Proteins from Mitochondria toward Cytosol in Living Cells and Animals.
A. Kanno, T. Ozawa and Y. Umezawa,
Anal. Chem., 78, 8076–8081 (2006).
- A. Method for Determining the Activities of Cytokines based on the Nuclear Transport of Nuclear Factor-κB.
S.B. Kim, Y. Natori, T. Ozawa, H. Tao, Y. Umezawa,
Anal. Biochem., 359, 147–149 (2006).
- Intein-Mediated Reporter Gene Assay for Detecting Protein–Protein Interactions in Living Mammalian Cells.
A. Kanno, T. Ozawa, Y. Umezawa,
Anal. Chem., 78, 556–560 (2006).
- Frontiers in Bioimaging,
M. Takeuchi and T. Ozawa,
ACS Chem. Biol., 1, 333–334 (2006).
- Designing Split Reporter Proteins for Analytical Tools.
T. Ozawa,
Anal. Chim. Acta, 556, 58–68 (2006).
- Quantitative Determination of Protein Nuclear Transport Induced by Phosphorylation or by Proteolysis.
S.B. Kim, R. Takao, T. Ozawa, Y. Umezawa,
Anal. Chem., 77, 6928–6934 (2005).
- A Genetically Encoded Indicator for Assaying Bioactive Chemicals that Induce Nuclear Transport of Glucocorticoid Receptor.
S.B. Kim, T. Ozawa, Y. Umezawa,
Anal. Biochem., 347, 213–220 (2005).
- Genetically Encoded Stress Indicator for Noninvasively Imaging Endogenous Corticosterone in Living Mice.
S.B. Kim, T. Ozawa, Y. Umezawa,
Anal. Chem., 77, 6588–6593 (2005).
- A High-Throughput Screening of Genes that Encode Proteins Transported into the Endoplamsic Reticulum in Mammalian Cells,
T. Ozawa, K. Nishitani, Y. Sako, Y. Umezawa,
Nucleic. Acids Res., 33, e34 (2005).
- Methods of Analysis for Protein Dynamics in Living Cells Based on Protein Splicing.
T. Ozawa,
Bull Chem. Soc. Jpn., 78, 739–751 (2005).
- Methods of Analysis for Chemicals that Disrupt Cellular Signaling Pathways:
Risk Assessment for Potential Endocrine Disruptors,
Y. Umezawa, T. Ozawa, M. Sato, H. Inadera, S. Kaneko, M. Kunimoto, S. Hashimoto,
Enviomental Sci., 12, 49–64 (2005).
- High-Throughput Sensing and Noninvasive Imaging of Protein Nuclear Transport by Using Reconstitution of Split Renilla Luciferase.
S. B. Kim*, T. Ozawa*, S. Watanabe, Y. Umezawa,
Proc. Natl. Acad. Sci. USA., 101, 11542–11547 (2004). (* Equal contribution to this work)
- Locating a Protein–Protein Interaction in Living Cells via Split Renilla Luciferase Complementation.
A. Kaihara, Y. Kawai, M. Sato, T. Ozawa and Y. Umezawa,
Anal. Chem., 75, 4176–4181 (2003).
- A Screening Method for Estrogens Using an Array-type DNA Glass Slide.
S. B. Kim, T. Ozawa, and Y. Umezawa,
Anal. Sci., 19, 499–504 (2003).
- A Genetic Approach to Identifying Mitochondrial Proteins.
T. Ozawa, Y. Sako, M. Sato, T. Kitamura, and Y. Umezawa,
Nature Biotechnol., 21, 287–293 (2003).
- A Genetic Approach to Identifying Organelle-Localized Proteins,
T. Ozawa, Y. Sako, Y. Umezawa,
Proceedings of the ISBC 2003, 276–279 (2003).
- Peptide Assemblies in Living Cells. Methods for Detecting Protein–Protein Interactions,
T. Ozawa and Y. Umezawa,
Supramol. Chem., 14, 271–280 (2002).
- Probing Chemical Processes in Living Cells: Application for Assay and Screening of Chemicals that Disrupt Cellular Signaling Pathways,
Y. Umezawa, T. Ozawa, M. Sato,
Bull. Chem. Soc. Jpn., 75, 1423–1433 (2002).
- Fluorescent Indicators for Imaging Protein Phosphorylation in Single Living Cells.
M. Sato, T. Ozawa, K. Inukai, T. Asano, and Y. Umezawa,
Nature Biotechnol., 20, 287–294 (2002).
- Peptide Assemblies in Living Cells. Methods for Detecting Protein–Protein Interactions.
T. Ozawa and Y. Umezawa,
Supramolecular Chemistry, 14, 271–280 (2002).
- Methods of Analysis for Chemicals that Promote/Disrupt Cellular Signaling.
Y. Umezawa, T. Ozawa and M. Sato,
Anal. Sci., 18, 503–516 (2002).
- Probing Chemical Processes in Living Cells: Application for Assay and Screening of Chemicals that Disrupt Cellular Signaling Pathways.
Y. Umezawa, T. Ozawa and M. Sato,
Bull. Chem. Soc. Jpn., 75, 1423–1433 (2002).
- Assay and Screening Methods for Chemicals that Disrupt Cellular Signaling Pathways. Risk Assessment for Potential Endocrine Disruptors.
Y. Umezawa, T. Ozawa and M. Sato,
Environmental Sciences, 9, 23–35 (2002).
- Protein Splicing-Based Reconstitution of Split Green Fluorescent Protein for Monitoring Protein–Protein Interactions in Bacteria: Improved Sensitivity and Reduced Screening Time.
T. Ozawa, M. Takeuchi, A. Kaihara, M. Sato and Y. Umezawa,
Anal. Chem., 73, 5866–5874 (2001).
- A Screening Method for Antagonists that Inhibit the Binding of Calmodulin to a Target Peptide Using Surface Plasmon Resonance.
K. Sasaki, T. Ozawa and Y. Umezawa,
Anal. Chim. Acta, 447, 63–74 (2001).
- Detection of Protein–Protein Interactions in vivo Based on Protein Splicing.
T. Ozawa and Y. Umezawa,
Curr. Opin. Chem. Biol., 5, 578–583 (2001).
- Imaging of Conformational Changes of Proteins with a New Environment-Sensitive Fluorescent Probe Designed for Site-Specific Labeling of Recombinant Proteins in Live Cells.
J. Nakanishi, T. Nakajima, M, Sato, T, Ozawa, K. Tohda and Y. Umezawa,
Anal. Chem., 73, 2920–2928 (2001).
- Split Luciferase as an Optical Probe for Detecting Protein–Protein Interactions in Mammalian Cells Based on Protein Splicing.
T. Ozawa, , A. Kaihara, M. Sato, K. Tachihara and Y. Umezawa,
Anal. Chem., 73, 2516–2521 (2001).
- Detection of Protein–Protein Interactions in vivo Based on Protein Splicing.
T. Ozawa and Y. Umezawa,
Curr. Opin. Chem. Biol., 5, 578–583 (2001).
- How Can Ca2+ Selectively Activate Recoverin in the Presence of Mg2+? Surface Plasmon Resonance and FT-IR Spectroscopic Studies.
T. Ozawa, M. Fukuda, M. Nara, A. Nakamura, K. Kohama and Y. Umezawa,
Biochemistry, 39, 14495–14503 (2000).
- Fluorescent Indicators for Cyclic GMP Based on Cyclic GMP-Dependent Protein Kinase Ia and Green Fluorescent Proteins.
M. Sato, N. Hida, T. Ozawa and Y. Umezawa,
Anal. Chem., 72, 5918–5924 (2000).
- A Fluorescent Indicator for Detecting Protein–Protein Interactions in Vivo Based on Protein Splicing.
T. Ozawa, S. Nogami, M. Sato, Y. Ohya and Y. Umezawa,
Anal. Chem., 72, No. 21, 5151–5157 (2000).
- A Screening Method for Substrates of Multidrug Resistance-Associated Protein (MRP).
Z. Quan, T. Ozawa, M. Sato and Y. Umezawa,
Anal. Chim. Acta, 423, 197–203 (2000).
- An SPR-based Screening Method for Agonist Selectivity for Insulin Signaling Pathways Based on the Binding of Phosphotyrosine to its Specific Binding Protein.
T. Yoshida, M. Sato, T. Ozawa and Y. Umezawa,
Anal. Chem., 72, 6–11 (2000).
- Novel Interaction of the Voltage-Dependent Sodium Channel (VDSC) with Calmodulin: Does VDSC Acquire Calmodulin-Mediated Ca2+-Sensitivity?
M. Mori, T. Konno, T. Ozawa, M. Murata, K. Imoto and K. Nagayama,
Biochemistry, 39, 1316–1323 (2000).
- Metal Ion Selectivity for Formation of the Calmodulin-Metal-Target Peptide Ternary Complex Studied by Surface Plasmon Resonance Spectroscopy.
T. Ozawa, K. Sasaki and Y. Umezawa,
Biochim. Biophys. Acta, 1434, 211–220 (1999).
- A Fluorescent Indicator for Tyrosine Phosphorylation-Based Insulin Signaling Pathways.
M. Sato, T. Ozawa, T. Yoshida and Y. Umezawa,
Anal. Chem., 71, 3948–3954 (1999).
- An Assay Method for Evaluating Chemical Selectivity of Agonists for Insulin Signaling Pathways Based on Agonist-Induced Phosphorylation of a Target Peptide.
T. Ozawa, M. Sato, M. Sugawara and Y. Umezawa,
Anal. Chem., 70, 2345–2352 (1998).
- An Optical Method for Evaluating Ion Selectivity for Calcium Signaling Pathways in the Cell.
T. Ozawa, M. Kakuta, M. Sugawara, Y. Umezawa and M. Ikura,
Anal. Chem., 69, 3081–3085 (1997).
総説、著書
- タンパク質翻訳後修飾細胞内イメージング
服部満,小澤岳昌,
ここまで進んだバイオセンシング・イメージング,日本化学会編,化学同人,p108-113 (2012).
- 生体分子と細胞内シグナルの可視化分析法
小澤岳昌
ヒューマンサイエンス,23(4), p12-16(2012).
- 分子イメージング−基礎から創薬までの新展開(座談会)
宮脇敦史,小澤岳昌,高松哲郎,長野哲雄
ヒューマンサイエンス,23(4), p4-11(2012).
- タンパク質核内移行の可視化
菅野憲,小澤岳昌
生体の科学,65, 494-495 (2011).
- 見つけることに意義がある−1分子計測技術の可能性−
上村想太郎,小澤岳昌,加地範匡,権田幸祐
現代化学,488, p26-30 (2011).
- 写真で見る日本化学の源流
佐藤健太郎,小澤岳昌
化学,66, p43-47 (2011).
- プローブタンパク質
小澤岳昌
蛍光イメージング/MRIプローブの開発,菊地和也監修,シーエムシー出版p22-34 (2011).
- 対象別試料分析法 5.4.5 細胞
菅野憲,小澤岳昌
分析化学便覧,日本分析化学会編,p516-522 (2011).
- 生命分子科学
小澤岳昌
学術の動向, 5月号, 53-57 (2011).
- 発光タンパク質による細胞活動リアルタイム観察,
小澤岳昌
BIOINDUSTRY, 28, 11-17(2011).
- 蛍光・発光タンパク質を用いた再構成法による分子イメージング,
小澤岳昌,
実験医学., 28, 27–32 (2010).
- 生細胞内mRNAイメージングの現状と課題
小澤岳昌
生命現象を理解する分子ツール,浜地格,二木史朗編,化学フロンティア(22),p33–40(2010).
- 生体分子と生理機能を可視化するタンパク質再構成法
小澤岳昌,
シングルセル解析の最前線,神原秀記,松永是,植田充美(監修),40–48,(2010).
- 生体分子の機能を可視化するGFP再構成法
小澤岳昌,
化学と工業,62,129–132(2009).
- 新領域開拓の先導的立場を担う化学
小澤岳昌,
化学,vol.64, 21–22,(2009).
- 光る遺伝子
小澤岳昌(監訳),Marc Zimmer(著),大森充香(訳),
丸善(2009).
- RNAとタンパク質局在のイメージング(新しい地平をひらく分析手法の最前線)
小澤岳昌,
化学フロンティア,北森武彦編,111–118,化学同人(2009).
- 発光タンパク質で細胞内をみる
小澤岳昌,
未来材料,vol. 9,28–35,エヌ・ティー・エス(2009).
- 蛍光タンパク質の設計と応用
小澤岳昌,
バイオ超分子,第4章 1-4,エヌ・ティー・エス(2009).
-
小澤岳昌,
「RNAイメージング法」
実験医学増刊,26,59–67(2008).
-
菅野憲,小澤岳昌,
「レポータータンパク質の再構成法を利用した生体分子イメージング」
生体の科学,59,66–72(2008).
-
小澤岳昌,
「タンパク質再構成法を用いた細胞内生体分子の解析法」
BIOINDUSTRY,25,27–36(2008).
- クラゲから生まれたGFP革命」
小澤岳昌,宮脇敦史,現代化学,12月号,25–28,東京化学同人(2008).
- 可視化プローブによる時空間情報を損なわないミトコンドリアRNAの動態観察」
小澤岳昌,ナノイメージング,第4編 1-1,199–206,エヌ・ティー・エス(2008).
- 生体機能を可視化する新たな分子プローブ」
小澤岳昌,ナノメディシン,宇理須恒雄編,13–24,オーム社(2008).
-
小澤岳昌,「光プローブの新しいデザインと生体機能の可視化」化学工業,58,860–864(2007).
- 「細胞の構造と機能:細胞内」
小澤岳昌,ナノテクのためのバイオ入門,荻野俊郎,宇理須恒雄編,第1章,共立出版(2007).
- フローサイトメーター
小澤岳昌,
ぶんせき,384, 640–641 (2006).
- 新しい蛍光タンパク質とその応用
小澤岳昌,梅澤喜夫
ゲノム医学,6,277–280 (2006).
- マウス個体におけるタンパク質動態イメージング
小澤岳昌,
細胞工学,25,1019–1022 (2006).
- 細胞内情報を視覚化するタンパク質試薬
小澤岳昌,
高分子,55, 343 (2006).
-
タンパク質の局在を知る—プロテインスプライシングを利用したイメージング技術の開発
小澤岳昌,
バイオニクス,3, 52–57 (2006).
- スプリットルシフェラーゼを用いた細胞内シグナル解析法
小澤岳昌,
バイオテクノロジージャーナル,6, 225–228 (2006).
- バイオテクノロジーにおける生物発光
小澤岳昌,
バイオ・ケミルミネセンスハンドブック,今井一洋,近江谷克裕編, 第1章1.4.2 ,丸善株式会社(2006).
-
Inteins for Split-Protein Reconstitutions and Their Applications.
T. Ozawa, Y. Umezawa, M.
Belfort (ed.), Nucleic Acids and Molecular Biology, Vol.16, 307–323, Springer-Verlag/Berlin (2005).
-
ミトコンドリア局在タンパク質を同定するプローブ分子
小澤岳昌,
化学測定の辞典,梅澤喜夫編,II–3,朝倉書店,(2005).
-
蛍光・発光タンパク質プローブの新たなデザインと細胞内オルガネラを標的としたプロテオミクス
小澤岳昌,
ぶんせき, 359, 637–639 (2004).
-
タンパク質間相互作用の生体での非破壊イメージング
小澤岳昌,梅澤喜夫,
実験医学,22, 529–533 (2004). - FACS
小澤岳昌,
先端の分析法—理工学からナノ・バイオまで,監修 梅澤喜夫,澤田嗣郎,寺部茂,第1編第4章第6節, エヌ・ティー・エス,(2004).
- 細胞内オルガネラ局在タンパク質同定法
小澤岳昌,
先端の分析法—理工学からナノ・バイオまで,監修 梅澤喜夫,澤田嗣郎,寺部茂,第1編第3章第12節, エヌ・ティー・エス,(2004).
- 酵母two-hybrid法(in vivo)ほか
小澤岳昌,
先端の分析法—理工学からナノ・バイオまで,監修 梅澤喜夫,澤田嗣郎,寺部茂,第1編第3章第11節, エヌ・ティー・エス,(2004).
- reporter gene assay
小澤岳昌,
先端の分析法—理工学からナノ・バイオまで,監修 梅澤喜夫,澤田嗣郎,寺部茂,第1編第3章第3節, エヌ・ティー・エス,(2004).
- Western blotting
小澤岳昌,
先端の分析法—理工学からナノ・バイオまで,監修 梅澤喜夫,澤田嗣郎,寺部茂,第1編第3章第2節, エヌ・ティー・エス,(2004).
- 高等動物にも存在したプロテインスプライシング
小澤岳昌,
化学,化学同人,61–62,9月号(2004).
- “カット&ペースト”で機能性タンパク質をつくる—プロテインスプライシングに学ぶ合成技術—
小澤岳昌,
現代科学,東京化学同人,49–54, 5月号(2004).
- インテイン
小澤岳昌,
Molecular Medicine, 40, 1384–1386 (2003).
- 環境—環境汚染物質のリスク評価・高速スクリーニング法—
小澤岳昌,
ぶんせき, 346, 592–596 (2003).
- 生細胞内情報伝達の蛍光可視化プローブ
梅澤喜夫,佐藤守俊,小澤岳昌
ぶんせき, 337, 18–25 (2003).
- タンパク質プローブ
佐藤守俊,小澤岳昌,梅澤喜夫,
現代科学,東京化学同人,25–31,2月号(2003)
- 共焦点レーザー走査型蛍光顕微鏡
小澤岳昌,
機器分析実験,編集 梅澤喜夫,本水昌二,渡会仁,寺前紀夫,第8章第1節,東京化学同人,(2002).
- 表面プラズモン共鳴法
小澤岳昌,
機器分析実験,編集 梅澤喜夫,本水昌二,渡会仁,寺前紀夫,第9章第2.3節,東京化学同人,(2002).
2001年
- 共焦点レーザ走査型蛍光顕微鏡
小澤岳昌,
界面ハンドブック,監修 岩澤康裕,梅澤喜夫,澤田嗣郎,辻井薫,第1編第2章第5節, エヌ・ティー・エス,(2001).
- 固定化ペプチド
小澤岳昌,
界面ハンドブック,監修 岩澤康裕,梅澤喜夫,澤田嗣郎,辻井薫,第1編第5章第3節, エヌ・ティー・エス,(2001).
-
内分泌撹乱化学物質の細胞内標的分子の同定と新しいバイオモニタリング.産婦人科の実際
小澤岳昌,梅澤喜夫,
(特集:内分泌撹乱化学物質(環境ホルモン)とその問題点), 49, 1113–1122 (2000).
-
レセプター蛋白に基づく化学センシング—生理適合性を有するアゴニスト選択性の評価法—.
菅原正雄,小澤岳昌,平野愛弓,中西淳,佐藤守俊,梅澤喜夫,
表面,35, 660–668 (1997).
-
Receptor Based Chemical Sensing.
M. Sugawara, H. Sato, T. Ozawa, Y. Umezawa, F. W. Sheller, F. Schubert and J. Fedrowitz (eds.),
Frontiers in Biosensorics, I, Fundamental Aspects, 121–131, Birkhäuser Verlag Basel/Switzerland (1997).
-
信号伝達のバイオセンサー
平野愛弓,小澤岳昌,菅原正雄,梅澤喜夫(分担執筆),
生物のスーパーセンサー,生物物理学会編, 172&–181, 共立出版 (1997).
-
膜レセプタセンサ
小澤岳昌,梅澤喜夫,
最新の分離・精製・検出法—原理から応用まで,監修 梅澤喜夫,澤田嗣郎,中村洋,第1編第3章第2節4.4.5, エヌ・ティー・エス,(1997).