Department of Chemical Engineering and Materials Science, Facalty of Sceince and Engineering, Doshisha University
Analytical Chemistry (Separation and Detection) Laboratory

List of Publication

List of Publication

  1. Fundamental Studies on Chemiluminescent Complex Compound Catalyst as Labeling Agent: Kazuhiko Tsukagoshi, Motohiro Toriyama, and Tadashi Hara, Kazuhiko Tsukagoshi and Tadashi Hara, The Science and Engineering Review of Doshisha University, 23, 119-129 (1982).
  2. Determination of a Small Amount of Biological Constituent by Use of Chemiluminescence. I. The Flow-injection Analysis of Protein: Tadashi Hara, Motohiro Toriyama, and Kazuhiko Tsukagoshi, Bulletin of the Chemical Society of Japan, 56,1382-1387 (1983).
  3. Immunoassay Using a Metal-complex as a Chemiluminescent Catalyst. I. Iron(III)phthalocyanine as a Labeling Reagent: Tadashi Hara, Motohiro Toriyama, and Kazuhiko Tsukagoshi, Bulletin of the Chemical Society of Japan, 56, 2267-2271 (1983).
  4. Immunoassay Using a Metal-complex as a Chemiluminescent Catalyst. II. An Improvement of the Analytical Method for Practical Use: Tadashi Hara, Motohiro Toriyama, and Kazuhiko Tsukagoshi, Bulletin of the Chemical Society of Japan, 56, 2965-2968 (1983).
  5. Determination of a Small Amount of Biological Constituent by Use of Chemiluminescence. II. Determination of Albumin as a Model Protein by Means of the Flow-injection Analysis using a Cobalt(III) Complex Compound as a Catalyst: Tadashi Hara, Motohiro Toriyama, and Kazuhiko Tsukagoshi, Bulletin of the Chemical Society of Japan, 57, 298-290 (1984).
  6. Immunoassay Using a Metal-complex as a Chemiluminescent Catalyst. III. Flow-through Analysis of a Labeled Antigen Bound by Immune Reaction: Tadashi Hara, Motohoro Toriyama, and Kazuhiko Tsukagoshi, Bulletin of the Chemical Society of Japan, 57, 587-588 (1984).
  7. Determination of a Small Amount of Biological Constituent by Use of Chemiluminescence. III. The Flow-injection Analysis of Protein by Direct Injection: Tadashi Hara, Motohiro Toriyama, and Kazuhiko Tsukagoshi, Tadashi Hara, Motohiro Toriyama, and Kazuhiko Tsukagoshi, Bulletin of the Chemical Society of Japan, 57,1551-1555 (1984).
  8. Determination of a Small Amount of Biological Constituent by Use of Chemiluminescence. VIII. Effect of Heating on the Determination of Protein: Tadashi Hara, Kazuhiko Tsukagoshi, Akihiro Arai, and Takeshi Iharada: Bulletin of the Chemical Society of Japan, 59, 3681-3683 (1986).
  9. Determination of a Small Amount of Biological Constituent by Use of Chemiluminescence. X. The Determination of Protein using a 1,10-Phenanthroline - Hydrogen - Peroxide - Ruthenium(III) System: Tadashi Hara, Kazuhiko Tsukagoshi, and Masakatsu Imaki: Tadashi Hara, Motohiro Toriyama, and Kazuhiko Tsukagoshi, Bulletin of the Chemical Society of Japan, 60,.1537-1539 (1987).
  10. Determination of a Small Amount of Biological Constituent by Use of Chemiluminescence. XI. The Determination of Protein using a 1,10-Phenanthroline - Hydrogen - Peroxide - Osmium(III) System: Tadashi Hara and Kazuhiko Tsukagoshi: Tadashi Hara, Motohiro Toriyama, and Kazuhiko Tsukagoshi, Bulletin of the Chemical Society of Japan, 60, 2031-2035 (1987).
  11. Adsorption of Protein onto Porous Sillica Bead. Determination of Protein Concentration in Aqueous Solution by Use of a Chemiluminescence Detector: Kazuhiko Tsukagoshi, Hideshi Kimoto, Masakatsu Imaki, and Tadashi Hara, The Science and Engineering Review of Doshisha University, 28, 104-114 (1987)
  12. Determination of a Small Amount of Biological Constituent by Use of Chemiluminescence. XII. Highly Sensitive Immunoaffinity Chromatography: Tadashi Hara, Kazuhhiko Tsukagoshi, Akihiro Arai, and Takeshi Iharada: Bulletin of the Chemical Society of Japan, 61, 301-303 (1988).
  13. Determination of a Small Amount of Biological Constituent by Use of Chemiluminescence. XIII. High Sensitive Metal Chelae Affinity Chromatography: Tadashi Hara, Kazuhiko Tsukagoshi, and Tatsunari Yoshida: Bulletin of the Chemical Society of Japan, 61, 2779-2783 (1988).
  14. Determination of a Small Amount of Biological Constituent by Use of Chemiluminescence. XIV. The Flow-injection Analysis of Protein Using Ultrasonic Chemiluminescence of Luminol: Tadashi Hara, Kazuhiko Nakatsu, Akihiro Arai, Tatsunari Yoshida, and Kazuhiko Tsukagoshi, Bulletin of the Chemical Society of Japan, 61, 2996-2998 (1988).
  15. Studies on the Method for the Determination of a Small Amount of Protein by the Use of Chemiluminescence. Method Inhibiting the Catalytic Activity of a Chemiluminescence Catalyst: Kazuhiko Tsukagoshi and Tadashi Hara, The Science and Engineering Review of Doshisha University, 28, 179-189 (1988).
  16. Investigation of the Complex Formation Between Cobalt(III) and Bovine Serum Albumin by Use of Chemiluminescence Detection: Kazuhiko Tsukagoshi and Tadashi Hara, The Science and Engineering Review of Doshisha University, 29, 1-6 (1988).
  17. A Highly Sensitive Fiber-Optic Immunosensor Using a Metal-Complex Compound as a Chemiluminescence Catalyst: Tadashi Hara, Kazuhiko Tsukagoshi, Akihiro Arai, and Yuji Imashiro: Bulletin of the Chemical Society of Japan, 62, 2844-2848 (1989).
  18. Improvement in FIA System for Detemining Small Amounts of Proteins with Chemiluminescence Detection: Bunseki Kagaku, Kazuhiko Tsukagoshi, Hideshi Kimoto, and Tadashi Hara, 38, T100-T103 (1989).
  19. Determination of a Small Amount of Biological Constituent by Use of Chemiluminescence. XV. A Zeolite Column - Chemiluminescence Detection System for the Separation and the Determination of a Protein Mixture: Tadashi Hara, Kazuhiko Tsukagoshi, and Yuichiro Kurita, Bulletin of the Chemical Society of Japan, 62, 1501-1508 (1989).
  20. Determination of a Small Amount of Biological Constituent by Use of Chemiluminescence. XVI. High-Sensitive Detection of Proteins by an Ion-Exchange Chromatograph - Chemiluminescence Detector System: Tadashi Hara, Kazuhiko Tsukagoshi, and Haruhiko Tsuji: Bulletin of the Chemical Society of Japan, 63, 770-776 (1990).
  21. Determination of a Small Amount of Biological Constituent by Use of Chemiluminescence. XVII. Experimental Consideration on the Chemiluminescence Detector of Protein using the 1,10-Phenanthroline - Hydrogen - Peroxide - Copper(II) System: Tadashi Hara, Kazuhiko Tsukagoshi, Hideshi Kimoto, Toshihiko Imai, and Riichiro Nakajima: Bulletin of the Chemical Society of Japan, 63, 2423-2425 (1990).
  22. Chemiluminescence of L-tryptophan in Copper(II) - Hydrogen Peroxide - Potassium Sodium Tartrate System: Tadashi Hara, Kazuhiko Tsukagoshi, Toshihito Imai, Naoki Yoshida, and Riichiro Nakajima, Chemistry Letters, 1990, 843-846.
  23. Chemiluminescence Analysis of Biological Constituents Using Metal-Complex Catalysts. A Review: Tadashi Hara and Kazuhiko Tsukagoshi, Analytical Sciences, 6, 797-806 (1990).
  24. Chemiluminescence of L-tryptophan in Copper(II) - Iron(II) - Hydrogen Peroxide - Potassium Sodium Tartrate System: Tadashi Hara, Kazuhiko Tsukagoshi, Naoki Yoshida, and Riichiro Nakajima, The Science and Engineering Review of Doshisha University, 31, 303-310 (1991).
  25. Specific Complexation with Mono- and Disaccharides That can Be Detected by Circular Dichroism: Kazuhiko Tsukagoshi and Seiji Shinkai, The Journal of Organic Chemistry, 56, 4089-4091 (1991).
  26. Molecular Recognition of Mono- and Di-saccharides by Phenylboronic Acids in Solvent Extraction and as a Monolayer: Seiji Shinkai, Kazuhiko Tsukagoshi, Yuichi Ishikawa, and Toyoki Kunitake, J. Chem. Soc., Chem. Commun., 1991, 1039-1041.
  27. Adsorption of Metal Ions onto Carboxylated Microspheres Synthesized by Seed Emulsion Polymerization: Yu Kaiyu, Hirotsugu Kido, Kazuhiko Tsukagoshi, Mizuo Maeda, and Makoto Takagi, Bunseki Kagaku (Japanese), 41, 459-461 (1992).
  28. Metal Ion-Imprinted Microspheres Prepared by Reorganization of the Coordinating Groups on the Surface: Kai Yu Yu, Kazuhiko Tsukagoshi, Mizuo Maeda, and Makoto Takagi, Analytical Sciences, 8, 701-703 (1992).
  29. Metal Ion Complexation Behavior of Resins Prepared by a Novel Template Polymerization Technique: Hirotsugu Kido, Kazuhiko Tsukagoshi, Mizuo Maeda, Makoto Takagi, and Toru Miyajima, Analytical Sciences, 8, 749-753 (1992).
  30. Template Polymerization Resin as a Separation Analysis Material: Kazuhiko Tsukagoshi and Makoto Takagi, Kagaku, 7, 500-5001 (1990).
  31. Separation and Detection of Saccharides by Capillary Electrophoresis–Laser Excitation Fluorescence Detction: Kazuhiko Tsukagoshi, Bunseki, 903-904 (1993).
  32. Metal Ion-Selective Adsorbent Prepared by Surface-Imprinting Polymerization: Kazuhiko Tsukagoshi, Kai Yu Yu, Mizuo Maeda, and Makoto Takagi, Bulletin of the Chemical Society of Japan, 66, 114-120 (1993).
  33. Adsorption behavior of metal ions Co(II)-imprinted microspheres prepared by surfice imprinting. Effect of Co(II)-imprinting: Kazuhiko Tsukagoshi, Kai Yu Yu, Mizuo Maeda, and Makoto Takagi, Kobunnshi Ronbun-shu (Japanese), 50, 455-458 (1993).
  34. Metal-ion complexation equilibria of ion-exchange resins prepared by a surfice template polymerization: Kobunnshi Ronbun-shu (Japanese), Hirotsugu Kido, Hidehiro Sonoda, Kazuhiko Tsukagoshi, Mizuo Maeda, and Makoto Takagi, 50, 403-410 (1993).
  35. Specific Complexation of Glucose with a Diphenylmethane-3,3'-diboronic Acid Derivative: Correlation between the Absolute Configuration of Mono- and Di-saccharides and the Circular Dichroic Activity of the complex: Yutaka Shiomi, Miwako Saisho, Kazuhiko Tsukagoshi, and Seiji Shinkai, J. Chem. Soc., Perkin Trans. I, 1993, 2111-2117.
  36. Specific Complexation of Saccharides with Dimeric Phenylboronic Acid that Can Be Detected by Circular Dichroism, Yutaka Shiomi, Kaoru Kondo, Miwako Saisho, Takaaki Harada, Kazuhiko Tsukagoshi, and Seiji Shinkai, Supramolecular Chemistry, 2, 11-17 (1993).
  37. Preparation and Sugar Binding Property of Microspheres Having Surface-anchored Phenylboronic Acid Groups: Kazuhiko Tsukagoshi, Rika Kawasaki, Mizuo Maeda, and Makoto Takagi, Chemistry. Letters, 1994, 681-684.
  38. Separation and Determination of Trace Dinitropyrenes by Means of Off-Line Reduction - HPLC - Chemiluminescence Detection. Application to Assessing Atmospheric Environment: Mizuo Maeda, Kazuhiko Tsukagoshi, Masaharu Murata, Makoto Takagi, Analytical Sciences, 10, 583-587 (1994).
  39. Template-Dependent Metal Adsorptivity of Dialkyl Phosphate-Type Resins Prepared by Surface Template Polymerization Technique: Mizuo Maeda, Masaharu Murata, Kazuhiko Tsukagoshi, and Makoto Takagi, Analytical Sciences, 10, 113-115 (1994).
  40. Novel Development of Template Polymerization as Molecular Recognition Host-Compound Synthesis: Kazuhiko Tsukagoshi, Chemistry & Industry, 555-556 (1994).
  41. Surface Imprinting. Characterization of a Latex Resin and the Original of the Imprinting Effect: K. Tsukagoshi, K. Y. Yu, M. Maeda, M. Takagi, and Tohru Miyajima, Bulletin of the Chemical Society of Japan, 68, 3095-3103 (1995).
  42. Preparation and Characterization of Polymer Microspheres Which Have Specific Binding Ability for Saccharide Molucules: Kazuhiko Tsukagoshi, Rika Kawasaki, Mizuo Maeda, and Makoto Takagi, Analytical Sciences, 12, 721-726 (1996).
  43. Characterization of Dyestuff-containing Liposome by Capillary Zone Electrophoresis Using On-line Chemiluminescence detectin: Kazuhiko Tsukagoshi, Hideshi Akasaka, Riichiro Nakajima, and Tasashi Hara, Chemistry Letters, 1996, 467-468.
  44. On-line Capillary Zone electrophoretic Separation-Chemiluminescence detection of Proteins Labeled with Fluorescamine: Kazuhiko Tsukagoshi, Akiko Tanaka, Riichiro Nakajima, and Tadashi Hara, Analytical Sciences, 12, 525-528 (1996).
  45. Electrophoretic Behavior of Dyestuff-Containing Liposome in Capillary with Original On-Line Chemiluminescence Detection: Kazuhiko Tsukagoshi, Yasuo Okumura, Hideshi Akasaka, Riichiro Nakajima, and Tadashi Hara, Analytical Sciences, 12, 869-874 (1996).
  46. Performance of a Coiled Capillary of One-cm Diameter in Capillary Electrophoresis: Kazuhiko Tsukagoshi, Ayumi Kenmochi, Riichiro Nakajima, and Tadashi Hara, Analytical Sciences, 12, 811-814 (1996).
  47. Information of Analytical Chemistry Provided through Internet: Takashi Tamura, Kazuhiko Tsukagoshi, and Riichiro Nakajima, Bunnseki, 10, 840-844 (1996).
  48. Synthesis and Polymerization of Template Resin Using an Interface: Kazuhiko Tsukagoshi, Mizuo Maeda, and Makoto Takagi, Bunseki Kagaku, 45, 975-986 (1996).
  49. New Development of Template Polymerization. Creation of Functionality by taking advantage of an Interface: Kazuhiko Tsukagoshi, Doshisha Kogaku Kaiho, 38, 43-58 (1996).
  50. Preparation of Phenylboronic Acid-Modified Capillary and Separation of Nucleosides by Capillary Electrophoresis: Kazuhiko Tsukagoshi, Masahiko Hashimoto, Kazuma Ichien, Shoukun Gen, and Riichiro Nakajima, Analytical Sciences, 13, 485-487 (1997).
  51. Electrophoretic Separation and High-Sensitivity Detection of Dyestuff-Labeled Proteins Using an Untreated Fused-Silica Capillary and Sodium Dodecyl Sulfate-Containing Buffer for Migration and Labeling: Kazuhiko Tsukagoshi, Masahiko Hashimoto, and Riichiro Nakajima, Analytical Sciences, 13, 565-570 (1997).
  52. High-sensitive Analysis of Heme Proteins Separated by Capillary Electrophoresis with On-line Chemiluminescence Detection Using a Luminol and Hydrogen Peroxide System: Kazuhiko Tsukagoshi, Shigehiro Fujimura, and Riichiro Nakajima, Analytical Sciences, 13, 279-281 (1997).
  53. High-Sensitivity Determination of Emetine Dithiocarbamate Copper(II) Complex Using the Electrogenerated Chemiluminescence Detection of Tris(2,2'-bipyridine)ruthenium (II): Kazuhiko Tsukagoshi, Kazuhide Miyamoto, Eiji Saiko, Riichiro Nakajima, Tadashi Hara, and Kaoru Fujinaga, Analytical Sciences, 13, 639-642 (1997).
  54. Chemiluminescence Property of the Luminol-hydrogen Peroxide-copper(II) System in the Presence of Surface-carboxylated Microspheres: Kazuhiko Tsukagoshi, Masayuki Sumiyama, Riichiro Nakajima, Masamichi Nakayama, and Mizuo Maeda, Analytical Sciences, 14, 409-412 (1998).
  55. Migration Behavior of Dyestuff-containing Liposomes in Capillary Electrophoresis with Chemiluminescence Detection: Kazuhiko Tsukagoshi, Yasuo Okumura, and Riichiro Nakajima, Journal of Chromatography A, 813, 402-407 (1998).
  56. Separation Behavior of Biological Constituents Having cis-Diol Groups through the Interaction with Phenylboronic Acid Sites Introduced on the Inner Wall of Fused-Silica Capillary: Kazuhiko Tsukagoshi, Masahiko Hashimoto, Miwa Otsuka, Riichiro Nakajima, and Kazuo Kondo, Bulletin of the Chemical Society of Japan, 71, 2831-2836 (1998).
  57. Basic Study on Electropherogram of Bovine Serum Albumin Denatured by Heating: Kazuhiko Tsukagoshi, Masahiko Hashimoto, Riichiro Nakajima, and Kazuo Kondo, The Science and Engineering Review of Doshisha University, 39 (3), 1-6 (1998).
  58. Surface Imprinting. Metal-ion Imprinted Resin Prepared by Using Complexation at the Aqueous-Organic Interface: Kazuhiko Tsukagoshi, Kai Yu Yu, Yoshihisa Ozaki, Tohru Miyajima, Mizuo Maeda, and Makoto Takagi, ACS Symposium Series 703, "Molecular and Ionic Recognition with Imprinted Polymers", R. A. Bartsch and M. Maeda Eds., Chapter 17, p.251, 1998.
  59. Consideration on Labeling of Bovine Serum Albumin with Rhodamine B Isothiocyanate by the Use of Electropherogram: Masahiko Hashimoto, Kazuhiko Tsukagoshi, Riichiro Nakajima, and Kazuo Kondo, The Science and Engineering Review of Doshisha University, 39 (4), 189-1192 (1999).
  60. Compact Detection Cell Using Optical Fiber for Sensitization and Simplification of Capillary Electrophoresis-Chemiluminescence Detector: Masahiko Hashimoto, Kazuhiko Tsukagoshi, Riichiro Nakajima, and Kazuo Kondo, Journal of Chromatography A, 832, 191-202 (1999). .
  61. Chemiluminescence Detection of Heme Proteins Separated by Capillary Isoelectric Focusing: Masahiko Hashimoto, Kazuhiko Tsukagoshi, Riichiro Nakajima, and Kazuo Kondo, Journal of Chromatography A, 852, 597-601 (1999).
  62. Chemiluminescence Detection in Microchip Capillary Electrophoresis: Masahiko Hashimoto, Kazuhiko Tsukagoshi, Riichiro Nakajima, and Kazuo Kondo, Chemistry Letters, 1999, 781-782.
  63. Simple and Convenient Cell for Chemiluminescence Detection in Capillary Electrophoresis: Kazuhiko Tsukagoshi, Takeshi Nakamura, Masahiko Hashimoto, and Riichiro Nakajima, Analytical Sciences, 15, 1047-1048 (1999).
  64. Batch-Type Detection Cell Using a Peroxyoxalate Chemiluminescence System for Capillary Electrophoresis: Kazuhiko Tsukagoshi, Miwa Otsuka, Masahiko Hashimoto, Riichiro Nakajima, and Kazuo Kondo, Analytical Sciences, 15, 1257-1260 (1999).
  65. Design of Pressure-Mobilization System for Capillary Isoelectric Focusing - Chemiluminescence Detection: Masahiko Hashimoto, Kazuhiko Tsukagoshi, Riichiro Nakajima, and Kazuo Kondo, Analytical Sciences, 15, 1281-1284 (1999).
  66. Flow-type Chemiluminescence Detectiion Cell Using Optical Fiber for Capillary Electrophoresis: Masahiko Hashimoto, Takeshi Nakamura, Kazuhiko Tsukagoshi, Riichiro Nakajima, and Kazuo Kondo, Bulletin of the Chemical Society of Japan, 72, 2673-2679 (1999).
  67. Simple and Sensitive Detection Cell for Capillary Electrophoresis - Chemiluminescence Analysis Using Peroxyoxalate Reagent: Kazuhiko Tsukagoshi, Miwa Otsuka, Masahiko Hashimoto, Richiro Nakajima, and Hideshi Kimoto, Chemistry Letters, 2000, 98-99.
  68. Microchip Capillary Electrophoresis Using On-Line Chemiluminescence Detection: Masahiko Hashimoto, Kazuhiko Tsukagoshi, Riichiro Nakajima, Kazuo Kondo, Akihiro Arai, Journal of Chromatography A, 867, 271-279 (2000).
  69. Immunoassay Using Chemiluminescence Detection of Dyestuff-Containing Liposomes as a Labeling Reagent: Kazuhiko Tsukagoshi, Yasuo Okumura, Ryosuke Fukaya, Miwa Otsuka, Kazutoshi Fujiwara, Hiroyuki Umehara, Reiko Maeda, and Riichiro Nakajima, Analytical Sciences, 16, 121-124 (2000).
  70. Determination of α-Amino Acid Using a 1,10-Phenanthroline - Hydrogen Peroxide - Osmium(VIII) Chemiluminescence: Kazuhiko Tsukagoshi, Takao Fukuoka, Riichiro Nakajima, and Tadashi Hara, The Science and Engineering Review of Doshisha University, 41, 180-184 (1999).
  71. Peptides Separation by Aqueous Normal Phase Liquid Chromatography Using Hydrophilic Interaction: Kazuhiko Tsukagoshi, Kagaku-kogaku, 64, 676 (2000).
  72. Application of Microchip Capillary Electrophoresis with Chemiluminescence Detection to Analysis for Transition Metal Ions: Kazuhiko Tsukagoshi, Masahiko Hashimoto, Riichiro Nakajima, and Akihiro Arai, Analytical Sciences, 16, 1111-1112 (2000).
  73. Double-featured Chemiluminescence Reagent Prepared through Mixing Procedure and Its Application to the Detection of Heme Protein: Kazuhiko Tsukagoshi, Masayo Yamamoto, and Riichiro Nakajima, Analytical Sciences, 16, 1357-1359 (2000).
  74. Imprinting Polymerization for Recognition and Separation of Metal Ions: Kazuhiko Tsukagoshi, Masaharu Murata, and Mizuo Maeda, "Molecularly Imprinted Polymers", B. Sellergren ed., Elsevier, Chapter 9, p. 245 - 269, 2001.
  75. Improvement of Capillary Electrophoresis - Chemiluminescence Detection System for Using Polyacrylamide-Coated Capillary: Kazuhiko Tsukagoshi, Takahiro Kimura, Toshinari Fuji, Riichiro Nakajima, and Akihiro Arai, Analytical Sciences, 17, 345-347 (2001).   
  76. Enhanced Chemiluminescence of Bis(2,4,6-trichlorophenyl) Oxalate-Hydrogen Peroxide-Dyestuff System in the Presence of Polymer Particles: Kazuhiko Tsukagoshi, Yuji Tomita, and Riichiro Nakajima, Chemistry Letters, 2001, 486-487.
  77. Direct Observation of Extraction of Cu(II) into Microcapsules Containing 8-Quinolinol by Use of Capillary and Chemiluminescence Detection: Kazuhiko Tsukagoshi, Yukiteru Ouji, and Riichiro Nakajima, Chemistry Letters, 2001, 528-529.
  78. Application of Capillary Electrophoresis-Chemiluminescence Dectection Method to Immunoassay, Kauhiko Tsukagoshi, Jpn. J. Electroph., 45, 111-115 (2001).
  79. Sensitive Determination of Metal Ions by Liquid Chromatography with Tris(2,2'-bipyridine) ruthenium (II) complex electrogenerated Chemiluminescence Detection: Kazuhiko Tsukagoshi, Kazuhide Miyamoto, Riichiro Nakajima, and Naoki Ouchiyama, Journal of Chromatography A, 919, 331-337 (2001).
  80. Capillary Electrophoresis with Chemiluminescent Detection for Luminol Using Potassium Ferricyanide as a Catalyst: Kazuhiko Tsukagoshi, Yukiteru Ouji, and Riichiro Nakajima, Analytical Sciences, 17, 1003-1005.
  81. Migration Behavior of the Polymer Particles Possessing Carboxylate and Borate Moieites in Capillary Electrophoresis: Kazuhiko Tsukagoshi, Akinobu Yamaguchi, Nobuo Morihara, Riichiro Nakajima, Masaharu Murata, and Misuo Maeda, Chemistry Letters, 2001, 926-927.
  82. Influence of Silicon Membrane Interposed between Glass Plates on Microchip Capillary Electrophoresis with a Chemiluminescence Detector: Kazuhiko Tsukagoshi, Masahiko Hashimoto, Takaji Suzuki, Riichiro Nakajima, and Akihiro Arai, Analytical Sciences, 17, 1129-1131 (2001).  
  83. Consideration on Peak Shape in Batch-type Chemiluminescence Detection Cell for Capillary Electrophoresis: Kazuhiko Tsukagoshi, Miwa Otsuka, Yukihiro Shikata, and Riichiro Nakajima, Journal of Chromatography A, 930, 165-169 (2001).
  84. Application of Capillary Electrophoresis with Sensitive Detection to Analysis for Saccharide Molecules: Kazuhiko Tsukagoshi, Yuki Obata, Takaaki Kanamori, and Riichiro Nakajima, Analytical Sciences, in press.
  85. Development of Capillary Electrophoresis Equipped with Chemiluminescence Detector Using 1,10-Phenanthroline reagent: Kazuhiko Tsukagoshi, Akira Shimizu, and Riichiro Nakajima, The Science and Engineering Review of Doshisha University, 43, 78-80 (2002).
  86. Separation and Determination of Emetine Dithiocarbamate Metal Complexes by Capillary Electrophoresis with Chemiluminescence Detection of the Tris(2,2'-bipyridine) Ruthenium(II) Complex: Kazuhiko Tsukagoshi, Noriyoshi Okuzono, and Riichiro Nakajima, Journal of Chromatography A, 953, 283-289 (2002).
  87. Batch-Type Chemiluminescence Detection Cell for Sensitization and Simplification of Capillary Electrophoresis: Kazuhiko Tsukagoshi, Takeshi Nakamura, and Riichiro Nakajima, Analytical Chemistry, 74, 4109-4116 (2002).
  88. Analysis of a Biopolymer by Capillary Electrophoresis with a Chemiluminescence Detector Using a Polymer solution as the Separation Medium; Kazuhiko Tsukagoshi, Yukihiro Shikata, Riichiro Nakajima, Masaharu Murata, and Mizuo Maeda, Analytical Sciences, 18, 1195-1198 (2002).
  89. Small-sized Capillary Electrophoresis with Chemiluminescence Detector Equipped with Cross-intersection for Small Injection: Kazuhiko Tsukagoshi,, Takaji Suzuki, and Riichiro Nakajima, Analytical Sciences, 18, 1279-1280(2002).
  90. Miniaturization of Batch- and Flow-type Chemiluminescence Detector in Capillary Electrophoresis: Kazuhiko Tsukagoshi, Yuki Obata, and Riichiro Nakajima, Journal of Chromatography A, 971, 255-260 (2002).
  91. Separation and Determination of Phenolic Compounds by Capillary Electrophoresis with Chemiluninescence Detection; Kazuhiko Tsukagoshi, Takahide Kameda, Masayo Yamamoto, and Riichro Nakajima, Journal of Chromatography. A, 978, 213-220 (2002).
  92. Development of Capillary Electrophorresis - Chemiluminescence Detection System: Kazuhiko Tsukagoshi, Bunseki Kagaku, 52, 1-13 (2003).
  93. Development of Ultra-micro Flow Analysis with Chemiluminescence Detector: Kazuhiko Tsukagoshi, Keiko Taga, and Riichiro Nakajima, Analytical Sciences, 19, 977-978 (2003).
  94. Development of FIA Equipped with a Chemiluminescence Detector Using a Mixed Reagent of Luminol and 1,10-Phenanthroline: Kazuhiko Tsukagoshi, Masayuki Tahira, and Riichiro Nakajima, Analytical Sciences, 19, 1019-1023 (2003).
  95. a-Amino Acids Analysis by Capillary Electrophoresis with Chemiluminescence Detector Using Luminol-Hydrogen Peroxide-Cu(II) System: Kazuhiko Tsukagoshi, Koji Nakahama, and Riichiro Nakajima, Chemistry Letters, 32, 634-635 (2003).
  96. Simultaneous Analysis of Plural Samples in a CE-CL Detector Possessing Micro-Space Area for Reaction/Detection: Kazuhiko Tsukagoshi, Keiichi Ikegami, and Riichiro Nakajima, Analytical Sciences, 19, 1339-1340 (2003).
  97. Analytical Performance of Capillary Electrophoretic System with UV/CL or FL/CL Dual Detector: Kazuhiko Tsukagoshi, Kaori Sawanoi, Masayuki Kamekawa, and Riichiro Nakajima, Chemistry Letters, 32, 894-895 (2003).
  98. Capillary Electrophoresis - Chemiluminescence Detection System Equipped with the Consecutive Sample Injection Device: Kazuhiko Tsukagoshi, Koji Nakahama, and Riichiro Nakajima, Analytical Sciences, 20, 379-381 (2004).
  99. Preparation of an Iminodiacetic Acid-Modified Capillary and Its performance in Capillary Liquid Chromatography and Immobilized Metal Chelate Affinity Capillary Electrophoresis: Kazuhiko Tsukagoshi, Yasushi Shimadzu, Tatsuhiko Yamane, and Riichiro Najima, Journal of Chromatography A, 1040, 151-154 (2004).
  100. Selective Detection of Human Serum Albumin Using a Fused-Silica Capillary Modified with Anti-Human Serum Albumin: Kazuhiko Tsukagoshi, Hirofumi Indou, Kaori Sawanoi, Takako Oguni, and Riichiro Nakajima, Bulletin of the Chemical Society of Japan, 77, 1353-1357 (2004).
  101. Simultaneous Operation of Plural Separation Modes in Capillary Electrophoresis with a Chemiluminescence Detector Possessing a Micro-Space Area for Reaction/Detection: Kazuhiko Tsukagoshi, Takashi Tokunaga, and Riichiro Nakajima, Journal of Chromatography A, 1043, 333-335 (2004).
  102. Capillary Electrophoresis with Chemiluminescence Detector Using On-capillary Detection: Kazuhiko Tsukagoshi, Tatsuya Fujii, and Riichiro Nakajima, Chemistry Letters, 33, 1000-1001 (2004).
  103. Direct Detection of Biomolecules in a Capillary Electrophoresis-Chemiluminescence Detection System: Kazuhiko Tsukagoshi, Koji Nakahama, and Riichiro Nakajima, Analytical Chemistry, 76, 4410-4415 (2004).
  104. Peak Formation Due to Chemiluminescence Reaction through the Collapse of Laminar Flow Liquid-Liquid Ineterface in a Microreactor: Kazuhiko Tsukagoshi, Keiich Ikegami, Riichiro Nakajima, Kenichi Yamashita, and Hideaki Maeda, Chemistry Letters, 33, 1178-1179 (2004).
  105. Chemiluminescence Detection for Capillary Electrophoresis and Liquid Chromatography. A Review; Kazuhiko Tsukagoshi, The Science and Engineering Review of Doshisha University, 45, 165-186 (2005).
  106. Development of a Micro-Total Analysis System Incorporating Chemiluminescence Detection and Application to Detection of Cancer Markers: Kazuhiko Tsukagoshi, Naoya Jinno, Riichiro Nakajima, Analytical Chemistry, 77, 1684-1688 (2005).  
  107. Competitive Immunoassay Using Capillary Electrophoresis with Chemiluminescence Detector: Kazuhiko Tsukagoshi, Naoya Jinno, Riichiro Nakajima, Bulletin of the Chemical Society of Japan, 78, 1791-1794 (2005).
  108. Capillary Electrophoresis Apparatus Equipped with a Bioluminescence Detector Using a Batch- or Flow-Type Detection Cell: Kazuhiko Tsukagoshi, Masayuki Tahira, and Riichiro Nakajima, Journal of Chromatography A, 1094, 192-195 (2005)
  109. Capillary Electrophoretic System Incorporating an UV/CL Dual Detector: Kazuhiko Tsukagoshi, Kaori Sawanoi, and Riichiro Nakajima, Talanta, 68, 1071-1075 (2006).
  110. Observation of the Complex Formation Between Cu(II) and Protein by Capillary Electrophoretic System Incorporating an UV/CL Dual Detector: Kazuhiko Tsukagoshi, Kaori Sawanoi, and Riichiro Nakajima, Journal of Chromatography B, 833, 174-178 (2006).
  111. Chemiluminescence from Singlet Oxygen under Laminar Flow Condition in a Micro-channel: Kazuhiko Tsukagoshi, Kazuaki Fukumoto, Keiichi Noda, Riichiro Nakajima, Kennchi Yamashita, Hideaki Maeda, Analytica Chimica Acta, 570, 202-206 (2006).
  112. Molecular Recognition of Mono- and Disaccharides through Interaction with p-Iodophenylboronic Acid in Capillary Electrophoresis with a Chemiluminescence Detection System: Kazuhiko Tsukagoshi, Kyohei Matsumoto, Futoshi Ueno, Keiichi Noda, Riichiro Nakajima, Koji Araki, Journal of Chromatography A, 1123, 106-112 (2006).
  113. Compact Polytetrafluoroethylene Assembly-Type Capillary Electrophoresis with Chemiluminescence Detection: Kazuhiko Tsukagoshi, Shingo Ishida, Yuichi Oda, Keiichi Noda, and Riichiro Nakajima, Journal of Chromatography A, 1125, 144-116 (2006).
  114. Effect of Additives in the running Buffer on alpha –Amino Acids Analysis by Use of Capillary Electrophoresis-Chemiluminescence Detection System: Kazuhiko Tsukagoshi, Koji Nakahama,, Keiichi Noda, Riichiro Nakajima, and Takao Fukuoka, The Science and Engineering Review of Doshisha University, 47, 62-70 (2006).
  115. Migration Behavior of Isoluminol Isothiocyanate-labeled Alpha-amino Acids in Capillary Electrophoresis with an Absorption/chemiluminescence Dual Detection System: Kazuhiko Tsukagoshi, Kaori Sawanoi, and Riichiro Nakajima, Journal of Chromatography A, 1143, 288-290 (2007).
  116. Enhancing Effect of Phenylboronic Acid Compounds and Their Interactions with the Diol Groups of Saccharides in a Capillary Electrophoresis-chemiluminescence Detection System: Kazuhiko Tsukagoshi, Futoshi Ueno, Riichiro Nakajima, and Koji Araki, Analytical Sciences, 23, 227-230 (2007).
  117. Analysis of Antioxidants using a Capillary Electrophoresis with Chemiluminescence Detection System: Kazuhiko Tsukagoshi, Takehito Taniguchi, and Riichiro Nakajima, Analytica Chimica Acta, 589, 66-70 (2007).
  118. Characterization of Chemiluminescence from Singlet Oxygen under Laminar Flow Conditions in a Micro-channel and its Quenching with Beverages: Kazuhiko Tsukagoshi, Kazuaki Fukumoto, Riichiro Nakajima, Kenichi Yamashita, and Hideaki Maeda, Talanta, 72, 607-611 (2007).
  119. Development od an Immune Microannalysis System by Use of Peroxyoxalate Chemiluminescence's Detection: Kazuhiko Tsukagoshi, Kazumasa Tsuge, and Riichiro Nakajima, Analytical Science, 23, 739-741 (2007).
  120. Effect of Saliva on Measurement of Chemiluminescence by a Micro-Reactor Incorporating a Micro-Channel: Kazuhiko Tsukagoshi, Kazuaki Fukumoto, Riichiro Nakajima, Kenichi Yamashita, and Hideaki Maeda, The Science and Engineering Review of Doshisha University, 48, 134-139 (2007).
  121. Micro-flow System Comprised of a Fused-Silica Capillary and Chemiluminescence Detection that Works under Laminar Flow Conditions: Kazuhiko Tsukagoshi, Shingo Ishida, and Riichiro Nakajima, Journal of Chemical Enguneering of Japan, 41, 130-137 (2008).
  122. Specific Chemiluminescence from Singlet Oxygen Generated by the Reaction of Acetonitrile and Hydrogen Peroxide in the Presence of Alkali Halide; Kosuke Suzuki, Hirotaka Saito, Naoya Jinno, Masahiko Hashimoto, Kazuhiko Tsukagoshi, and Hideshi Kimoto, Chemistry Letters, 37, 1090-1091 (2008).
  123. Microchip Electrophoresis: Masahiko Hashimoto and Kazuhiko Tsukagoshi, Bunseki, 544-550 (2008).
  124. Analysis of Antioxidants by Microchip Capillary Electrophoresis with Chemiluminescence Detection Based on Luminol Reaction; Kazuhiko Tsukagoshi, Takahiro Saito, and Riichiro Nakajima, Talanta, 77, 514-517 (2008).
  125. Micro-Channel Chemiluminescence Analysis Using Peroxyoxalate Reaction that Works through Liquid–liquid Interface Collapse under Laminar Flow Conditions; Kazuhiko Tsukagoshi, Yoshiyuki Hattori, Teruki Hayashi, Riichiro Nakajima, Kenichi Yamashita, and Hideaki Maeda, Analytical Sciences, 24, 1393-1398 (2008).
  126. Chemiluminescence from Singlet Oxygen That was Detected at Two Wavelengths And Effects of Biomolecules on It; Yusuke Harada, Kosuke Suzuki, Masahiko Hashimoto, Kazuhiko Tsukagoshi, Hideshi Kimoto, Talanta, 77, 1223-1227 (2008).
  127. Development of Capillary Electrophoresis Equipped with a Novel PTFE Cell for Chemiluminescence Detection; Misa Yanagiuchi, Kosuke Suzuki, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, The Science and Engineering Review of Doshisha University, 49, 187-192 (2009).
  128. Metal Ion Analysis Using Microchip CE with Chemiluminescence Detection Dased on 1,10-Phenanthroline-Hydrogen Peroxide Reaction; Takahiro Nogami, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Journal of Separation Science, 32, 408-412 (2009).
  129. Micro-Flow Separation System Using an Open Capillary Tube That Works under Laminar Flow Conditions; Naoya Jinno, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Analytical Sciences, 25, 145-147 (2009).
  130. Development of Novel Chemiluminescence Analysis Using Liquid-Liquid Interface Micro-Reaction Space in a Micro-Channel: Masahiko Hashimoto and Kazuhiko Tsukagoshi, Bunseki Kagaku, 56, 495-506 (2009).
  131. Capillary Chromatography Based on Tube Radial Distribution of Aqueous-Organic Mixture Carrier Solvents; Naoya Jinno, Minoru Itano, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Talanta, 79, 1348-1353 (2009).
  132. Capillary Chromatography Based on Tube Radial Distribution of Aqueous-Organic Mixture Carrier Solvents: Elution Behavior of Carboxylated Polymer Particles in the System; Naoya Jinno, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Journal of Chemical Engineering of Japan, 42, 767-770 (2009).
  133. Capillary Chromatography Based on Tube Radial Distribution of Aqueous-Organic Mixture Carrier Solvents: Effect of the Inner Wall Characteristics of the Fused-Silica Tube on Separation Performance; Naoya Jinno, Ko Hashimoto, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Analytical Sciences, 25, 1369-1371 (2009).
  134. Capillary Chromatography Based on Tube Radical Distribution of Aqueous-Organic Mixture Carrier Solvents; Introduction of Inner-Wall-Modified Capillary tube: Naoya Jinno, Katsuya Tsuji, Kaoru Shikatani, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Journal of Separation Science, 32, 4099-4100 (2009).
  135. Preparation of Zinc Oxide Ceramics with a Sustainable Antibacterial Activity under Dark Conditions: Ken Hirota, Maiko Sugimoto, Masaki Kato, Kazuhiko Tsukagoshi, Tooru Tanigawa, and Hiroshi Sugimoto, Ceramics International, 36, 497-506 (2010).
  136. Capillary Gel Electrophoresis for Ligase Detection Reaction Products: Masahiko Hashimoto, Jun Kamigori, and Kazuhiko Tsukagoshi, The Science and Engineering Review of Doshisha University,50, 164-170 (2010).
  137. Distribution of Fluorescent Dyes Dissolved in Ternary Mixed Solvent in a Micro-Channel under Laminar Flow Conditions: Mari Murakami, Naoya Jinno, Masahiko Hashimoto, Kazuhiko Tsukagoshi, Chemistry Letters, 39, 272-273 (2010).
  138. Synthesis of New Antibacterial ZnO Powders by Hydrothermal Treatment and their Characterization: Sho Matsuoka, Masaki Kato, Ken Hirota, and Kazuhiko Tsukagoshi, Journal of the Japan Society of Powder and Powder Metallurgy, 57, 106-111 (2010).
  139. Capillary Chromatography Based on Tube Radial Distribution of Aqueous–Organic Mixture Carrier Solvents: Introduction of Double Tubes Having Different Inner Diameters to the System: Koju Yamada, Naoya Jinno, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Analytical Sciences, 26, 507-510 (2010).
  140. Separation of Optical Isomers in Capillary Chromatography Using a Poly(tetrafluoroethylene) Capillary Tube and an Aqueous-Organic Mixture Carrier Solution: Seiji Ishimoto, Naoya Jinno, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Analytical Sciences, 26, 641-643 (2010).
  141. Elution Behavior of Proteins in Capillary Chromatography Using an Untreated Fused-silica Capillary Tube and a WaterHydrophilicHydrophobic Organic Mixture Carrier Solvent; Yuji Masuhara, Naoya Jinno, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Chemistry Letters, 39, 688-689 (2010).
  142. Analytical Conditions and Separation performance of Capillary Chromatography Based on the Tube Radical Distribution of Aqueous -Organic Mixture Carrier Solvents under laminar–Flow Conditions; Naoya Jinno, Mari Murakami, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Analytical Sciences, 26, 737-742 (2010).
  143. Capillary Electrophoresis with Absorption/Chemiluminescence's Dual Detection System Using a Poly(tetrafluoroethylene) Separation Capillary; Takayuki Tanaka, Naoya Jinno, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, The Science and Engineering Review of Doshisha University, 51, 77-81 (2010).
  144. Introduction of fluorescence and chemiluminescence detection to capillary chromatography based on tube radial distribution of water–hydrophilic–hydrophobic organic mixture carrier solvents; Seiji Ishimoto, Yudai Kudo, Naoya Jinno, Masahiko Hashimoto and Kazuhiko Tsukagoshi, Analytical Methods, 2, 1377-1381 (2010).
  145. Temperature Effect on Separation Performance in Capillary Chromatography based on Tube Radial Distribution of Aqueous-Organic Mixture Carrier Solvents; Naoya Jinno, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, The Science and Engineering Review of Doshisha University, 51, 168-172 (2010).
  146. Direct Detection of Mutant DNA in a Mixed Population of Higher Copy Number Wild-Type DNA Based on Ligase Detection Reaction in Conjunction with Fluorescence Resonance Energy Transfer; Masahiko Hashimoto,Kazuma Yoshida, and Kazuhiko Tsukagoshi, Analytical Sciences, 26, 1255-1299 (2010).
  147. Metal Compound Analysis by Capillary Chromatography Using an Untreated Capillary Tube and Water-Hydrophilic-Hydrophobic Solvent Mixture as a Carrier Solution; Kazuma Yoshida, Naoya Jinno, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, The Science and Engineering Review of Doshisha University, 51, 198-201 (2011).
  148. Fluorescence Observation Supporting Capillary Chromatography Based on Tube Radial Distribution of Carrier Solvents under Laminar Flow Conditions; Naoya Jinno, Mari Murakami, Kiyoshi Mizohata, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Analyst, 136, 927-932 (2011).
  149. Experimental Consideration of Capillary Chromatography Based on Tube Radial Distribution of Ternary Mixture Carrier Solvents under Laminar Flow Conditions; Naoya Jinno, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Analytical Sciences, 27, 259-264 (2011).
  150. Extraction of Cu(II) Based on Tube Radial Distribution of Ternary Mixed Carrier Solution in Microchannels; Naoya Jinno, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Chemistry Letters, 40, 654-655 (2011).
  151. Development of DNA Point Mutation Detction Methods Using Probe DNA-Immobilized Microbeads: Masahiko Hashimoto, Yusuke Tamai, and Kazuhiko Tsukagoshi, The Science and Engineering Review of Doshisha University,52, 93-98 (2011).
  152. Tube Radial Distribution Phenomenon of Ternary Mixed Solvents in a Microspace under Laminar Flow Conditions; Mari Murakami, Naoya Jinno, Masahiko Hashimoto, Kazuhiko Tsukagoshi, Analytical Sciences, 27, 793-798 (2011).
  153. Derivatization of a Protein with Fluorescamine Utlizing the Tube Radial Distribution Phenomenon of Ternary Mixed Carrier Solvents in a Capillary Tube; Yuji Masuhara, Naoya Jinno, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Chemistry Letters, 40, 804-805 (2011).
  154. Use of Tube Radial Distribution of Ternary Mixed Carrier Solvents for Introduction of Absorption Reagent for Metal Ion Separation and On-Line Detection into Capillary; Satoshi Fujinaga, Naoya Jinno, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Journal of Separation Science, 34, 2833-2839 (2011).
  155. Components of the Carrier Solvents and Separation Performance in the Tube Radial Distribution Chromatography Using a Fused-Silica Capillary tube; Naoya Jinno, Yoichiro Hashimoto, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, The Science and Engineering Review of Doshisha University, 52, 177-180 (2011).
  156. Development of Capillary Chromatography Based on Specific Solvent Molecule Bahavior in Microspac; Satoshi Fujinaga and Kazuhiko Tsukagoshi, Transactions of the Research Institute of Oceanochemistry, 24, 81-85 (2011).
  157. Instrumentation of a PLC-Regulated Temperature Cycler with a PID Control Unit and Its Use for Miniaturized PCR Systems with Reduced Volumes of Aqueous Sample Droplets Isolated in Oil Phase in a Microwell; Masahiko Hashimoto, Masayuki Torii, Kazuma Yoshida, Keiichi Noda, and Kazuhiko Tsukagoshi, Analytical Sciences, 27, 1191-1196 (2011).
  158. Microfluidic Reactor for Sequential Operation of Polymerase Chain Reaction/Ligase Detection Reaction; Masahiko Hashimoto, Kazuhiko Tsukagoshi, and Steven A. Soper, Journal of Advanced Chemical Engineering, 1, 1-12 (2011).
  159. Influences of Analyte Injection Volumes and Concentrations on Capillary Chromatography Based on Tube Radial Distribution of Carrier Solvents under Laminar Flow Conditions; Yusuke Tanigawa, Naoya Jinno, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Chromatography, 32, 135- 140 (2011).
  160. Rapid and Convenient Sample Preparation in a Single Tube Using Magnetic Beads for Fluorescence Detection of Single Nucleotide Variation Based on Oligonucleotide Ligation; M. Hashimoto, C. Morimoto, K. Hagihara, and Kazuhiko Tsukagoshi, Chemistry Letters, 41, 135-137 (2012).
  161. Effects of Tube Materials on Capillary Chromatography Based on Tube Radial Distribution of Ternary Mixture Carrier Solvents under Laminar Flow Conditions; Yudai Kudo, Naoya Jinno, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Chromatorgaphia, 75, 417-421 (2012).
  162. Tentative Comparison of Tube Radial Distribution Chromatography and CZE; Kisuke Tabata, Naoya Jinno, Keiichi Noda, Masahiko Hashimoto, Kazuhiko Tsukagoshi, Chromatorgaphia, 75, 423-428 (2012).
  163. Separation of Dansyl-DL-Amino Acids by Open Tubular Capillary Chromatography Based on Tube Radial Distribution Phenomenon of the Ternary Mixed Carrier Solvents; Yudai Kudo, Hyo Kan, Naoya Jinno, Masahiko Hashimoto and Kazuhiko Tsukagoshi, Analytical Methods, 4, 906-912 (2012).
  164. Capillary Electrophoresis with a Chemiluminescence Detector Using the Two Reactions of Luminal and Peroxyoxalate; Kazumasa Tsuge, Takayuki Tanaka, Keiichi Noda, and Kazuhiko Tsukagoshi, Journal of Liquid Chromatography & Related Technologies, 35, 1091–1101 (2012).
  165. Biomolecule Analyses in an Open-Tubular Capillary Chromatography Using Ternary Mixed Carrier Solvents with Chemiluminescence Detection; Naoya Takahashi, Yuji Masuhara, Naoya Jinno, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Analytical Sciences, 28, 351-357 (2012).
  166. Mixing Process of Ternary Solvents Prepared through Microchannels in a Microchip under Laminar Flow Conditions; Kei Nishiyama, Naoya Jinno, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Analytical Sciences, 28, 423-427 (2012).
  167. Experiments and Considerations through the Phase Diagram in Open Tubular Capillary Chromatography Based on Tube Radial Distribution of Ternary Mixed Solvents Using a Fused-Silica Capillary Tube; Yusuke Tanigawa, Naoya Jinno, Masahiko Hashimoto, Kazuhiko Tsukagoshi, American Journal of Analytical Chemistry, 3, 300-3005 (2012).
  168. The Micro-Flow Reaction System Featured the Liquid-Liquid Interface Created with Ternary Mixed Carrier Solvents in a Capillary Tube; Yuji Masuhara, Naoya Jinno, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Analytical Sciences, 28, 439-444 (2012).
  169. Consideration of the Tube Radial Distribution of the Carrier Solvents in a Capillary Tube under Laminar Flow Conditions and Computer Simulation; Naoya Jinno, Yuji Masuhara, Tomoya Kobayashi, Naoya Takahashi, Yusuke Tanigawa, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Analytical Sciences, 28, 527-530 (2012).
  170. Elution Behavior of Lambda-DNA with Ternary Mixed Carrier Solvents in an Open-Tubular Capillary under Laminar Flow Conditions; Takahiro Nogami, Satoshi Fujinaga, Naoya Jinno, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Analytical Sciences, 28, 617-620 (2012).
  171. Study of Outer Phases in Capillary Chromatography, Based on Tube Radial Distribution of Carrier Solvents under Laminar Flow Conditions; Naoya Jinno, Mari Murakami, Kiyoshi Mizohata, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Journal of Liquid Chromatography & Related Technologies, 35, 1750–1766 (2012).
  172. Microfluidic Behavior of Ternary Mixed Carrier Solvents Based on the Tube Radial Distribution in Triple-Branched Microchannels in a Microchip; Naoya Jinno, Masahiko Hashimoto, Kazuhiko Tsukagoshi, Journal of Analytical Sciences, Methods and Instrumentation, 2, 49-53 (2012).
  173. Fluidic Behavior of Polymer Compounds in an Open-Tubular Capillary with Ternary Mixed Carrier Solvents under Laminar Flow Conditions; Takahiro Nogami, Satoshi Fujinaga, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Journal of Flow Injection Analysis, 29, 21-24 (2012).
  174. Influence of Adding Surfactants to an Analyte Solution on Separation Performance in Open-tubular Capillary Chromatography Based on the Tube Radial Distribution of Ternary Mixed Carrier Solvents; Katsuya Unesaki, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Chemistry Letters, 41, 855-856 (2012).
  175. Investigation into Tie Lines and Solubility Curves on Phase Diagrams in Open-Tubular Capillary Chromatography Using Ternary Mixed-Carrier Solvents; Yusuke Tanigawa, Satoshi Fujinaga, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Analytical Sciences, 28, 921-924 (2012).
  176. Tube Radial Distribution Phenomenon and its Application; Satoshi Fujinaga and Kazuhiko Tsukagoshi, Chemistry & MicroNanosystem, 11, 10-15 (2012).
  177. Chromatography Using Ternary Water­Acetonitrile­Ethyl Acetate Mixture as a Carrier Solution on a Microchip Incorporating Microchannels; Takafumi Matsuda, Naoya Jinno, Kenichi Yamashita, Hideaki Maeda, Akihiro Arai, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Chemistry Letters, 41, 1448-1450 (2012).
  178. Tube Radial Didtribution of Solvents Observed in an Aqueous Ionic Liquid Mixed Solution Delivered into a Capillary Tube; Yuki Kawai, Masaharu Murata, Masahiko Hashimoto, and Kazuhiko Tsikagoshi, Analytical Sciences, 28, 1029-1031 (2012).
  179. Specific microfluidic behavior of ternary mixed carrier solvents ofwater–acetonitrile–ethyl acetate in open-tubular capillary chromatographyand the chromatograms; Satoshi Fujinaga, Katsuya Unesaki, Shigeru Negi, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Analytical Methods, 4, 3884-3890 (2012).
  180. Capillary Chromatography Based on Tube Radial Distribution of Ternary Mixed Solvents: Construction of the Phase Diagram and the Separation Performance; Yusuke Tanigawa, Satoshi Fujinaga, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, The Science and Engineering Review of Doshisha University, 53, 167-172 (2013).
  181. Michrochip Chromatography Using an Open-Tubular Microchannel and a Ternary Water-Acetonitrile-Ethyl Acetate Mixture Carrier Solution; Takafumi Matsuda, Kenichi Yamashita, Hideaki Maeda, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Journal of Separation Science, 36, 965-970 (2013).
  182. Two-Phase Extraction of Metal Ions Using a Water-Acetonitrile-Ethyl Acetate Ternary Mixed-Solvent Separation System; Naoya Takahashi, Masahiko Hashimoto, and Kazuhiko Tsikagoshi, Analytical Sciences, 29, 665-667 (2013).
  183. Examination of Tube Radial Distribution Phenomenon and Its Function Appearance; Kazuhiko Tsukagoshi, Bunseki Kagaku, 62, 393-407 (2013).
  184. Specific Distribution Behavior of a Ternary Mixture of Solvents Fed into Bentand Wound Microchannels in Microchips, Kei Nishiyama, Masaharu Murata, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Analytical Sciences, 29, 1003-1008 (2013).
  185. Tube Radial Distribution Phenomenon Observed in an Aqueous Micellar Solution of Non-Ionic Surfactant Fed into a Microspace and Attempt to Capillary Chromatographic Application;N. Jinno, K. Unesaki, M. Hashimoto and K. Tsukagoshi, Journal of Analytical Chemistry, 68, 1197-1202 (2013).
  186. Rapid and Convenient Sample Preparation in a Single Tube Using Magnetic Beads for Fluorescence Detection of Single Nucleotide Variation Based on Oligonucleotide Ligation; Masahiko Hashimoto, Chika Morimoto, Kenta Hagihara, and Kazuhiko Tsukagoshi, Chem. Lett., 41, 135-137 (2012).
  187. Development of a PCR/LDR/Flow-Through Hybridization Assay Using a Capillary Tube, Probe DNA-Immobilized Magnetic Beads and Chemiluminescence Detection; Manami Hommatsu, Hisamitsu Okahashi, Keisuke Ohta, Yusuke Tamai, Kazuhiko Tsukagoshi, and Masahiko Hashimoto, Analytical Sciences, 29, 689-695 (2013).
  188. Development of a Ligase Detection Reaction/CGE Method Using a LIF Dual-Channel Detection System for Direct Identification of Allelic Composition of Mutated DNA in a Mixed Population of Excess Wild-Type DNA; Mariko Hamada, Koji Shimase, Keiichi Noda, Kazuhiko Tsukagoshi, Masahiko Hashimoto, Electrophoresis, 34, 1415-1422 (2013).
  189. Fundamental Research and Application of the Specific Fluidic Behavior of Mixed Solvents in a Microspace (Invited Review), Kazuhiko Tsukagoshi, Analytical Sciences, 30, 65-73 (2014).
  190. Tube Radial Distribution Phenomenon with a Two-phase Separation Solutionof a Fluorocarbon and Hydrocarbon Organic Solvent Mixture in a Capillary Tube and Metal Compounds Separation; Koichi Kitaguchi, Naoya Hanamura, Masaharu Murata, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Analytical Sciences, 30, 687-690 (2014).
  191. Microchip Capillary Chromatography with Chemiluminescence Detection Based on Tube Radial Distribution Phenomenon; Takafumi Matsuda, Masahiko Hashimoto, Kazuhiko Tsukagoshi, Luminescence (The Journal of Biological and Chemical Luminescence), 29, 49 (2014).
  192. Capillary Chromatography Using an Annular and Sluggish Flow in the Ternary Water–Acetonitrile–Ethyl Acetate System as Carrier Solution; Yuya Hamaguchi, Satoshi Fujinaga, Shunpei Murakami, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Chemistry Letters, 43, 1318-1320 (2014).
  193. Investigation of Inner and Outer Phase Formation in Tube Radial Distribution Phenomenon Using Various Types of Mixed Solvent Solutions; Satoshi Fujinaga, Katsuya Unesaki, Yuki Kawai, Koichi Kitaguchi, Kosuke Nagatanu, Masahiko Hashimoto, Kazuhiko Tsukagoshi, and Jiro Mizushima, Analytical Sciences, 30, 1005-1011 (2014).
  194. Open-Tubular Capillary Chromatography Based on Tube Radial Distribution of the Water-Acetonitrile Containing Sodium Chloride Mixture Carrier Solvents; Tomoya Kobayashi, Hyo Kan, Kisuke Tabata, Masahiko Hashimoto, andKazuhiko Tsukagoshi, Journal of Liquid Chromatography & Related Technologies, 38, 44-53 (2015).
  195. Microflow-Extraction System Using Double Tubes Having Different Inner Diameters in Tube Radial Distribution Phenomenon; Katsuya Unesaki, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, The Solvent Extraction Research and Development, Japan, 22, 87-93 (2015).
  196. Investigation of the Composition for a Ternary Solvent System in Tube Radial Distribution Chromatography; Satoshi Fujinaga, Masahiko Hashimito, and Kazuhiko Tsukagoshi, Journal of Liquid Chromatography & Related Technologies, 38, 600-606 (2015).
  197. Investigation of Tube Radial Distribution Phenomenon (TRDP) and Its Function Appearance; Kazuhiko Tsukagoshi, Kimura Keibun Sha, Chapters 1-14, pp. 1-372, September, 2015.
  198. Microfluidic Inverted Flow of Aqueous and Organic Solvent Mixed Solution in a Microchannel under Laminar Flow Conditions; Shunpei Murakami, Satoshi Fujinaga, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, The Science and Engineering Review of Doshisha University, 56, 155-159 (2015).
  199. Separation of Metal Complexes with Counter Ions by Tube Radial Distribution Chromatography Using a Ternary Solvent Containing 8-quinolinol; Yuji Kawai, Satoshi Fujinaga, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Analytical Sciences, 31, 1177-1182 (2015).
  200. Consideration of Tube Radial Distribution Phenomenon under Laminar Flow Conditions Based on the Weber Number; Satoshi Fujinaga, Masahiko Hashimoto, Kazuhiko Tsukagoshi, and Jiro Mizushima, Journal of Chemical Engineering of Japan, 48, 947-952 (2015).
  201. Tube Radial Distribution Chromatography on a Microchip Incorporating Microchannels with a Three-to-One Channel Confluence Point; Naomichi Suzuki, Kenichi Yamashita, Hideaki Maeda, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Analytical Sciences, 31, 1267-1272 (2015).
  202. Investigation of Specific Microfluidic Flow with Two-phase Separation Mixed Solvent Solutions and Application to Flow Technology; Kazuhiko Tsukagoshi, Journal of Flow Injection Analysis, 32, 89-95 (2015).
  203. Consideration of Inner and Outer Phase Configuration in Tube Radial Distribution Phenomenon Based on Viscous Dissipation in a Microfluidic Flow Using Various Types of Mixed Solvent Solutions; Satoshi Fujinaga, Masahiko Hashimoto, Kazuhiko Tsukagoshi, and Jiro Mizushima, Analytical Sciences, 32, 455-461 (2016).
  204. Microflow Extraction Using a Microchip Incorporating Microchannels Based on the Tube Radial Distribution Phenomenon; Naomichi Suzuki, Masahiko Hashimoto, and Kazuhiko Tsukagoshi, Solvent Extraction Research and Development, Japan, 23, 115-120 (2016).
  205. Novel Microfluidic Behavior Found Out in Microspace. Application to Chromatography; Kazuhiko Tsukagoshi, Kagaku, 71, 74-75 (2016).
  206. Tube Radial Distribution Flow Separation in a Microchannel Using an Ionic Liquid Aqueous Two-Phase System Based on Phase Separation Multi-Phase Flow; Kosuke Nagatani, Yoshinori Shihata, Takahiro Matsushita, and Kazuhiko Tsukagoshi, Analytical Sciences, 32, 1371-1374 (2016).
  207. Support for improving operations at hospital pharmacy department (Nara Prefectural University of Medicine · Doshisha University Collaborative Research Project Research Result Report); Setsuko Kajii and Kazuhiko Tsukagoshi, March 31, 2017.
  208. Protein Separation through Preliminary Experiments Concerning pH and Salt Concentration by Tube Radial Distribution Chromatography Based on Phase Separation Multiphase Flow Using a Polytetrafluoroethylene Capillary Tube; Hyo Kan andKazuhiko Tsukagoshi, Talanta, 169, 130-135 (2017).
  209. Microfluidic Analytical System with On-Line Luminol Chemiluminescence Detection Based on Annular Flow of Phase Separation Multiphase Flow; Junki Manai, Kei Nishiyama, and Kazuhiko Tsukagoshi, Journal of Analytical Sciences, Methods and Instrumentation, 7, 29-39 (2017).
  210. Denaturation of DNA in Ternary Mixed Solution of Water/Hydrophilic/Hydrophobic Organic Solvent;Yuki Ito, Kazuhiko Tsukagoshi, and Akira Kobayashi, Journal of Analytical Sciences, Methods and Instrumentation, 7, 40-46 (2017).
  211. Tube Radial Distribution Chromatography System Developed by Combining Commercially Available HPLC System and Open-Tubular Capillary Tube as Separation Column; Kento Yamada, Hyo Kan, and Kazuhiko Tsukagoshi, Talanta, 183, 89-93 (2018).
  212. Implementation of Tube Radial Distribution Chromatography by Using a Commercially Available HPLC System; Hyo Kan, Kento Yamada, Nobuyuki Sanada, Koyo Nakata, and Kazuhiko Tsukagoshi, Analytical Sciences, 34, 239-241 (2018).
  213. Preparation of ZnO Powders with Strong Antibacterial Activity under Dark Conditions; Thi Minh Phuong Nguyen, Shoko Hirota, Yusei SuZuki, Masaki Kato, Ken Hirota, Hideki TaGUCHI, Hirohisa Yamada, and Kazuhiko Tsukagoshi, Journal of the Japan Society of Powder and Power Metallurgy, 65, 316-324 (2018).
  214. Phase Separation Multi-Phase Flow Using an Aqueous Two-Phase System of a Polyethylene Glycol/Dextran Mixed Solution; Naoya Imanishi, Tetsuo Yamashita, Kazuhiko Tsukagoshi, and Masaharu Murata, Analytical Sciences, 34, 953-958 (2018).
  215. Microfluidic Inverted Flow of Ternary Water/Hydrophilic/Hydrophobic Organic Solvent Solution in a Y-Type Microchannel and a Proposal of the Response Microfluidic Analysis through the Experiment; Bun Yamawaki, Ryuki Mori, Kazuhiko Tsukagoshi, Katsumi Tsuchiya, Kenichi Yamashita, and Masaharu Murata, Analytical Sciences, 35, 249-256 (2019).
  216. Discovery of phase separation multiphase flow and its application to chromatographic separation technology; Kazuhiko Tsukagoshi, Separation Technology, 49, 24-28 (2019).
  217. Development of Tube Radial Distribution Chromatography Based on Phase-Separation Multiphase Flow Created via Pressure Loss; Susumu Wada, Kazuhiko Tsukagoshi, Katsumi Tsuchiya, Ken Hirota, Kenichi Yamashita, and Masaharu Murata, Analytical Sciences, 35, 803-806 (2019).
  218. The Study of Physicochemical Properties of Antibacterial ZnO Powder – Impurity Doping, Elution and Catalytic Properties –; Nguyen Phuong Thi Minh, Yuki Tokuoka, Wakana Imai, Ken Hirota, Masaki Kato, and Kazuhiko Tsukagoshi, The Harris Science Review of Doshisha University, 60, 105-113 (2019).
  219. Dependence of Antibacterial Activity of ZnO Powders on Their Physico-chemical Properties; Thi Minh Phuong Nguyen, Ken Hirota, Masaki Kato, Kazuhiko Tsukagoshi, Hirohisa yamada, Atsuki Terabe, and Hideto Mizutani, Journal of the Japan Society of Powder and Power Metallurgy, 66, 434-441 (2019).
  220. Mixing Process of Ternary Mixed Solvent Solutions in a Tapered-Microchannel and Application to Analysis method of Mixing Characteristics in Microfluidic Channel; Ryuki Mori, Yuko Nakata, Kazuhiko Tsukagoshi, Katsumi Tsuchiya, Ken Hirota, Kenichi Yamashita, and Masaharu Murata, Journal of Flow Injection Analysis, 36, 19-25 (2019).
  221. Confirmation of Separation Mechanism Through Visualization of Microfluidic Behavior of Fluorescent Analytes in Tube Radial Distribution Chromatography; Yoshuke Takatsuki, Katsumi Tsuchiya, Kenichi Yamashita, and Masaharu Murata, Chromatography, 40, 163-168 (2019).
  222. Phase separation and collection of annular flow by phase transformation; Aya Yoshioka, Kazuhiko Tsukagoshi, Katsumi Tsuchiya, Ken Hirota, Kenichi Yamashita, and Masaharu Murata, Analytical Sciences, 35, 1279-1282 (2019).
  223. Development of α-Amino Acid Detection with Peroxyoxalate Chemiluminescence by Using Water-Acetonitrile-Ethyl Acetate Mixed Solution; Hyo Kan, Ryo Mizutani, Kazuhiko Tsukagoshi, American Journal of Analytical Chemistry, 11, 2020, 15-24 (2020).
  224. Investigation of the Separation Efficiency of Tube Radial Distribution Chromatography with Stationary Outer Phase Using the van Deemter Equation; Chihiro Matsushita, Kazuhiko Tsukagoshi, Katsumi Tsuchiya, Kenichi Yamashita, Masaharu Murata, Chromatographia, 83, 287-292 (2020).
  225. Control of Phase Configuration of an Annular Flow in a Capillary Tube through a Mixing Joint; Ryota Shiraishi, Kazuhiko Tsukagoshi, Katsumi Tsuchiya, Ken Hirota, Kenichi Yamashita, Masaharu Murata, Journal of Flow Injection Analysis, 37, 13-18 (2020).
  226. Preparation of Anatase Titanium Dioxide NanoparticlePowders Submitting Reactive Oxygen Species (ROS) under Dark Conditions; Thi Minh Phuong Nguyen, Perrine Lemaitre, Masaki Kato, Ken Hirota, Kazuhiko Tsukagoshi, Hirohisa Yamada, Atsuki Terabe, Hideto Mizutani, Shingo Kanehira, Materials Sciences and Applications12, 89-110 (2021).
  227. Separation of Dansyl-DL-Amino Acids Through Tube Radial Distribution Chromatography by Using a Commercially Available HPLC System with a Capillary Tube Manufactured for GC as a Separation Column; Nobuyuki Ssanada, Kazuhiko Tsukagoshi, Katsumi Tsuchiya, Ken Hirota, Kenichi Yamashita Masaharu Murata, Chromatography42, 67-71 (2021).
  228. Consecutive Sample Injection analysis in Tube Radial Distribution Chromatography; Yusaku Takahashi, Kazushi Nishimura, Kazuhiko Tsukagoshi, Katsumi Tsuchiya, Ken Hirota, Kenichi Yamashita, and Masaharu Murata, Analytical Sciences, 37, 1373-1377 (2021).
  229. Microfluidic Behavior of Ternary Mixed Solutions of Water/Acetonitrile/Ethyl Acetate through Experiments and Computer Simulations; Keigo Yonekura, Kazushi Nishimura, Katsumi Tsuchiya, Kenichi Yamashita, Masaharu Murata, and Kazuhiko Tsukagoshi, Analytical Sciences, 38, 731-736 (2022).
  230. Discovery of Phase-Separated Multiphase Flows and Attempts at Academic and Technical Systematization; Kazuhiko Tsukagoshi, BUNSEKI KAGAKU, 71, 25-39 (2022).
  231. Novel Separation Mode of HPLC Based on Phase-Separation Multiphase Flow; Kosei Horikawa, Satoru Kinoshita, Katsumi Tsuchiya, and Kazuhiko Tsukagoshi, Analytical Sciences, 38, 931-933 (2022).
  232. Observation of the Phase-Separation Multiphase Flow Using a Polyethylene Glycol/Phosphate Mixed Solutions and the Aqueous Two-Phase Distribution of Red Blood Cells in the Flow System; Kazushi Nishimura, Chihiro Matsushita, Kenichi Yamashita, Masaharu Murata, and Kazuhiko Tsukagoshi, Analytical Sciences, 39, 537-546 (2023).
  233. Antibacterial Activity of Anatase TiO2 Added Cu Powder; Ken Hirota, Ayumu Jinzenji, Kazuhiko Tsukagoshi, Yurika Taniguchi, Hiroshi Kawakami, Takashi Ozawa, Masahiko Wada, and Yoji Yuki, Powder Powder Metallurgy, 70, 121-131 (2023).
  234. Development of HPLC System That Uses Phase-Separation Multiphase Flow as an Eluent; Noé Jallas, Daiki Ishikawa, Tetsuro Katayama, Aoi Kimura, Satoru Kinoshita, and Kazuhiko Tsukagoshi, Analytical Sciences, 39, 883-892 (2023).
  235. Development of a HPLC System Using a Phase-Separation Multiphase Flow as an Eluent Coupled to a Silica-Particle Packed Column; Satoru Kinoshita, Daiki Ishikawa, Yuki Kobayashi, Yuki Obata, Hiroshi Sakamaki, Takeshi Iharada, and Kazuhiko Tsukagoshi, Analytical Sciences, 39, 1483-1491 (2023).
  236. Evaluation of Reactive Oxygen Species (ROS) Generated on the Surface of Copper Using Chemiluminesence; Ken Hirota, Hiroya Tanaka, Taika Maeda, Kazuhiko Tsukagoshi, Hiroshi Kawakami, Takashi Ozawa, and Masahiko Wada, Materials Sciences and Applications, 14, 482-499 (2023).
  237. Phase-Separation Multiphase Flow: Preliminary Application to Analytical Chemistry; Kazuhiko Tsukagoshi, Analytical Sciences, 40, 9-28 (2024).
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