Kyushu University Academic Staff Educational and Research Activities Database
List of Presentations
Masahiro Goto Last modified date:2019.07.26

Professor / Applied Chemistry / Department of Applied Chemistry / Faculty of Engineering


Presentations
1. R. Sato, K. Minamihata, M. Goto, N. Kamiya, Design of a PolyTag that affords polymerization of functional proteins, The 15th Japan-China-Korea Joint Symposium on Enzyme Engineering, 2018.07.
2. 小坂秀斗, 中田孝広, 赤木淳二, 田嶋史郎, 國友栄治, 上田太郎, 松岡信也, 後藤雅宏, Utilization of Reverse Micelle Formulation for Transcutaneous Cancer Vaccine, The 31st International Symposium on Chemical Engineering, 2018.12.
3. A. Yamada, R. Wakabayashi, Y. Tahara, N. Kamiya, M. Goto, Effect of amino acids for transcutaneous vaccine using Solid-in-Oil nanodispersion, The 31th Int. Symp. Chem. Engineer., 2018.12.
4. 大林 洋貴, 若林 里衣, 神谷 典穂,後藤 雅宏, Creation of orderly co-assemblies consisted of peptide amphiphileand drugs through complementary interaction, ISChE2018, 2018.11.
5. R. Wakabayashi, H. Obayashi, N. Kamiya, M. Goto, Complemantary interaction with peptide amphiphiles guided the intracellular delivery of small molecular drugs, YABEC 2018 , 2018.11.
6. Q. Kong, M. Kitaoka, Y. Tahara, R. Wakabayashi, N. Kamiya, M. Goto, Development of intranasal vaccination using Solid-in-Oil technology, 化学工学会 第84年会, 2019.03.
7. Q. Kong, M. Kitaoka, Y. Tahara, R. Wakabayashi, N. Kamiya, M. Goto, Intranasal immunization by using Solid-in-Oil nanodispersions, The 31th International Symposium on Chemical Engineering , 2018.12.
8. Q. Kong, M. Kitaoka, R. Wakabayashi, N. Kamiya, M. Goto, Transcutaneous pollinosis immunotherapy using Solid-in-Oil nanodispersions loaded with T cell epitope peptides, 化学工学会第50回秋季大会, 2018.09.
9. Q. Kong, M. Kitaoka, Y. Tahara, R. Wakabayashi, N. Kamiya, M. Goto, Enhancement of transcutaneous vaccine delivery by using Solid-in-Oil nanodispersions with natural terpenes,, The 29th Young Researcher Symposium on Chemical Engineering in Kyushu District, 2018.07.
10. Y. Ohama, K. Minamihata, R. Wakabayashi, M. Goto, N Kamiya, Enzymatic hydrogelation of liquid marbles for in situ immobilization of cell-free synthesized recombinant proteins , The 24th Symposium of Young Asian Biological Engineers' Community, 2018.11.
11. 花田隆文, M. L. Firmansyah, 吉田航, 久保田富生子, 後藤雅宏, Polymer inclusion membrane containing trioctyl(dodecyl)phosphonium chloride for the separation of platinum group metals from spent automotive catalyst, The 31th International Symposium on Chemical Engineering, 2018.12.
12. 花田隆文, 岩熊美奈子, 後藤雅宏, Synthesis of polymer type extractant containing thiomethylfuran and its extraction behavior of precious metals, International Conference on Ion Exchange 2018, 2018.09.
13. R. M. Moshikur, R. Wakabayashi, Y. Tahara, M. Moniruzzaman, N. Kamiya, M. Goto, Salicylate amino acid esters as the novel Active Pharmaceutical Ingredient Ionic Liquids (API-ILs): characterization and cytotoxicity evaluation, 10th AFOB Regional Symposium (ARS 2018), 2018.01.
14. R. M. Moshikur, Y. Tahara, R. Wakabayashi, M. Moniruzzaman, N. Kamiya, M. Goto, Methotrexate Ionic liquid moieties as the potent anticancer prodrugs: Characterization and solubility evaluation, 6th Asian-Pacific Conference on Ionic Liquids & Green Processes (APCIL-6), 2018.11.
15. Y. Tahara, M. Kaho, R. Wakabayashi, N. Kamiya, M. Goto, Transdermal drug delivery mediated by ionic liquids, which dispersed drugs in oil-based penetration enhancer, The 24th Symposium of Young Asian Biological Engineer’s Community (YABEC 2018), 2018.11.
16. W. Yoshida, F. Kubota, S.D. Kolev, M. Goto, Separation of critical metal ions from iron(III) using a polymer inclusion membrane containing an amic acid carrier and quinone, The 31th Int. Symp. Chemical Engineering, 2018.12.
17. W. Yoshida, F. Kubota, S.D. Kolev, M. Goto, Extraction equilibria of scandium(III) with the amic acid-type extractants and application to a polymer inclusion membrane, 7th Int. Conf. Ion Exchange, 2018.09.
18. Masahiro Goto, Pharmaceutical Application of Ionic Liquids for Transdermal Drug Delivery Systems, The 6th Asian Pacific Conference on Ionic Liquids, (APCIL-6), 2018.11.
19. Masahiro Goto, Amic acid extractants applicable to industrial solvent extraction for the recovery of strategic metals, International Conference on Coordination Chemistry, 2018, (ICCC 2018), 2018.07.
20. Uju, Agung Tri Wijayanta, Masahiro Goto, Noriho Kamiya, High yield hydrolysis of seaweed-waste biomass using peracetic acid and ionic liquid treatments, 3rd International Conference on Industrial Mechanical, Electrical, and Chemical Engineering, ICIMECE 2017, 2018.02, Seaweed is one of the most promising bioethanol feedstocks. This water plant has high carbohydrate content but low lignin content, as a result it will be easier to be hydrolysed. This paper described hydrolysis of seaweed-waste biomass from the carrageenan (SWBC) industry using enzymatic saccharification or ionic liquids-HCl hydrolysis. In the first work, SWBC pretreated by peracetic acid (PAA) followed by ionic liquid (IL) caused enhance the cellulose conversion of enzymatic saccharification. At 48h saccharification, the value conversion almost reached 100%. In addition, the untreated SWBC also produced the cellulose conversion 77%. In the second work, SWBC or Bagasse with or without pretreated by PAA was hydrolyzed using ILs-HCl hydrolysis. The ILs used were 1-buthyl-3-methylpyridium chloride, [Bmpy][Cl] and 1-butyl-3-metyl imidazolium chloride ([Bmim][Cl]). [Bmpy][Cl]-HCl hydrolysis produced higher cellulose conversion than [Bmim][Cl]-HCl hydrolysis. The phenomenon was clearly observed on the Bagasse, which without pretreated by PAA. Furthermore, SWBC hydrolyzed by both ILs in the presence low concentration of HCl produced cellulose conversion 70-98% at 60-90 min of hydrolysis time. High cellulose conversion of SWBC on the both hydrolysis was caused by SWBC had the low lignin (4%). Moreover, IL treatments caused lowering of cellulose hydrogen bonds or even changed the cellulose characteristics from cellulose I to cellulose II which easily to be hydrolyzed. In the case of [Bmpy][Cl], this IL may reduce the degree polymerization of celluloses..
21. Masahiro Goto, Novel Cancer Vaccine by Transcutaneous Drug Delivery System Using Solid-in-Oil Nano Carrier, 10th AFOB Regional Symposium 2018, 2018.01.
22. M. R. Chowdhury, R. Wakabayashi, Y. Tahara, M. Moniruzzaman, N. Kamiya, M.Goto, Ionic Liquids Based Paclitaxel IV Injection: A New Potential Formulation for Cancer Treatment, 10th AFOB Regional Symposium 2018, 2018.01.
23. R. M. Moshikur, R. Wakabayashi, Y. Tahara, M. Moniruzzaman, N. Kamiya, M. Goto, Salicylate amino acid esters as the novel Active Pharmaceutical Ingredient Ionic Liquids (API-ILs): characterization and cytotoxicity evaluation, 10th AFOB Regional Symposium 2018, 2018.01.
24. W. Yoshida, Y. Baba, F. Kubota, S.D. Kolev, M. Goto, Membrane transport of critical metal ions and stability studies of polymer inclusion membranes, The 30th International Symposium on Chemical Engineering, 2017.12.
25. R. Kono, W. Yoshida, F. Kubota, M. Goto, Separation of Au(III) from mobile phones using a polymer inclusion membrane with D2EHAG as the carrier, The 30th International Symposium on Chemical Engineering, 2017.12.
26. Aiko Yamada, Rie Wakabayashi, Yoshiro Tahara, Noriho Kamiya, Masahiro Goto, Solid-in-Oil nanodispersion with an amino acid as a permeation enhancer for transcutaneous vaccine, The 30th International Symposium on Chemical Engineering, 2017.12.
27. H. Kouno, Y. Tahara, R. Wakabayashi, N. Kamiya, M. Goto, Development of transcutaneous cancer vaccine by oil-based nanodispersion technique, The 30th International Symposium on Chemical Engineering, 2017.12.
28. R. Wakabayashi, M. Katsuya, N. Kamiya, M. Goto, Multi-block fibrous assembly of peptide amphiphiles based on intrinsic immiscibility, The Second International Symposium on Biofunctional Chemistry (ISBC2017), 2017.12.
29. Kozaka Shuto, Nakata Takahiro, Akaki Junji, Tajima Shiro, Kunitomo Fiji, Goto Masahiro, Utilization of reverse micelles for skin permeation enhancement of bioactive macromolecules, The 30th ISChE, 2017.12.
30. W. Yoshida, Y. Baba, F. Kubota, S.D. Kolev, M. Goto, Separation of scandium(III) from lanthanides using a polymer inclusion membrane containing an amic acid-extrctant carrier, The 21st International Solvent Extraction Conference, 2017.11.
31. M. Sharif, W. Yoshida, F. Kubota, M. Goto, Selective extraction of scandium from other REEs using binary extractant of PC-88A and versatic10 from nitrate media, The 21st International Solvent Extraction Conference(ISEC2017), 2017.11.
32. M. L. Firmansyah, F. Kubota, M. Goto, Effective separation of Pt(IV), Pd(II), and Rh(III) in acidic solution by using phosphonium-based ionic liquids, The 21st International Solvent Extraction Conference(ISEC2017), 2017.11.
33. R. Kono, W. Yoshida, F. Kubota, M. Goto, Selective extraction and recovery of precious metals with a novel amic acid extractant from waste mobile phones, The 21st International Solvent Extraction Conference(ISEC2017), 2017.11.
34. 後藤 雅宏, 溶媒抽出プロセスに実利用可能な新規抽出剤の開発とその課題, 資源・素材&EARTH 2017, 2017.09.
35. Masahiro Goto, Cancer Vaccine by Transcutaneous Antigen-Peptide Delivery
Using Solid-in-Oil Technique
, APCChE 2017, 2017.08.
36. W. Yoshida, Y. Baba, F. Kubota, S.D. Kolev, M. Goto, Selective membrane transport of rare earth ions by a polymer inclusion membrane, The 17th Congress of the Asian Pacific Confederation of Chemical Engineering, 2017.08.
37. Masahiro Goto, TRANSDERMAL CANCER VACCINE BY SOLID-IN-OIL(S/O) NANODISPERSIONS, ACB 2017, 2017.07.
38. Qingliang Kong, Masahiro Goto, Transcutaneous immunotherapy for pollinosis using Solid-in-Oil Nanodispersion, 9th AFOB Regional Symposium, 2017.02.
39. Masahiro Goto, TRANSDERMAL CANCER VACCINE BY SOLID-IN-OIL(S/O) NANODISPERSIONS, 9th AFOB Regional Symposium, 2017.02.
40. Masato Sakuragi, Masahiro Goto, Solid-in-oil nanodispersions for transcutaneous cancer vaccine by induction of antitumor immunity against melanoma, The 29th International Symposium on Chemical Engineering, 2016.12.
41. Qingliang Kong, Masahiro Goto, Development of a transcutaneous immunotherapy for Japanese Cedar Pollinosis using Solid-in-Oil nanodispersions, The 29th International Symposium on Chemical Engineering, 2016.12.
42. Water Yoshida, Masahiro Goto, Development of polymer inclusion membranes containing an amid acid-type carrier for platinum group metal separation, The 29th International Symposium on Chemical Engineering, 2016.12.
43. Atsushi Oka, Masahiro Goto, Transcutaneous immunotherapy of Japanese ceder pollinosis using CpG as an adjuvant, The 29th International Symposium on Chemical Engineering, 2016.12.
44. Kouno Hideto, Masahiro Goto, Development of transcutaneous cancer vaccine by oil based nano dispersion technique, The 29th International symposium on Chemical Engineering, 2016.12.
45. Riho Kouno, Masahiro Goto, Recovery of precious metals from leach liquor of waste mobile phones with a novel amic acid extractant, The 29th International symposium on Chemical Engineering, 2016.12.
46. Rie Wakabayashi, Masahiro Goto, Enzyme-Reactive Self-Assembling Peptides for Biomacromolecular Functionalization, AIChE 2016 annual meeting, 2016.11.
47. Masahiro Goto, Solid-in-Oil (S/O) Nanodispersions for Transdermal Cancer Immunotherapy, AIChE 2016 annual meeting,, 2016.11.
48. Atsushi Oka, Masahiro Goto, Transcutaneous immunotherapy of Japanese ceder pollinosis with CpG as an adjuvant, The 22nd Symposium of Young Asian Biological Engineers’ Community, 2016.10.
49. Hidenao Kono, Masahiro Goto, Development of transcutaneous cancer vaccine by Solid-in-Oil technology, The 22nd Symposium of Young Asian Biological Engineers’ Community, 2016.10.
50. Qingliang Kong, Masahiro Goto, Development of Transcutaneous Pollinosis Immunotherapy by Solid-in-Oil technology, The 22nd Symposium of Young Asian Biological Engineers’ Community, 2016.10.
51. Qingliang Kong, Masahiro Goto, Transdermal pollinosis immunotherapy by Solid-in-Oil nanodispersions,, 化学工学会第48回秋季大会, 2016.09.
52. Masahiro Goto, Commercialization of Nano-capsules for Transdermal Drug Delivery Systems, Asian Federation of Biotechnology(AFOB) Summer Forum, 2016.08.
53. Masahiro Goto, Selective separation and recovery of strategically important metals using a polymer inclusion membrane containing an acidic extractant with alkylamide and amino acid moieties, IEX 2016: Ion Exchange, 2016.07.
54. Masahiro Goto, Challenge of Commercialization of Transdermal Drug Delivery Systems Invented in University, International Symposium on Biotechnology and Bioengineering, 2016.06.
55. Masahiro Goto, Challenge of Commercialization of Surfactant-Coating Nano Capsules Invented in University, International Colloid & Surfaces Symposium in Asia, 2016.06.
56. Masahiro Goto, New Extractants Applicable to Industrial Solvent Extraction Process for Rare Earth Separation, International Rare Earths Conference 2016, 2016.06.
57. Masahiro Goto, Activation of Biocatalysts in Ionic Liquids as a green reaction medium, International Catalysis Conference 2016, 2016.05.
58. Masahiro Goto, Cancer Immunotherapy by Transdermal Drug Delivery Systems Using Nano Coating Drug Carrier, ICES Seminar, 2016.05.
59. Rie Wakabayashi, Masahiro Goto, Enzyme-mediated assembly of biomolecules on a designer scaffold based on self-assembled peptides, The International Chemical Congress of Pacific Basin Societies 2015, 2015.12.
60. Masahiro Goto, New extractants applicable to industrial solvent extraction for the recovery of strategic metals, PacifChem 2015, 2015.12.
61. Wataru Yoshida, Masahiro Goto, Development of new extractant applicable to industrial solvent extraction for the recovery of precious metals, The 27th International Symposium on Chemical Engineering, 2015.12.
62. Yukiho Hosomomi, Masahiro Goto, Chemical modification of E. Coli and its application to the biosorption of metal ions, The 27th International Symposium on Chemical Engineering, 2015.12.
63. Oueng Kong, Masahiro Goto, Development of a transcutaneous pollinosis immunotherapy by using a solid-in-oil nanodispersion, The 28th International Symposium on Chemical Engineering, 2015.12.
64. Ayaka Suehiro, Masahiro Goto, Supramolecular Peptide Scaffold fr an Enzymatic Assembly of Functional Molecules, The 28th International Symposium on Chemical Engineering, 2015.12.
65. Takafumi Saeki, Masahiro Goto, Enzymatic assembly of proteins onto synthetic polymer scaffold, The 28th International Symposium on Chemical Engineering, 2015.12.
66. Takuji Kawakami, Masahiro Goto, Enzymatic Strategy for Lipidization of Functional Proteins, The 28th International Symposium on Chemical Engineering, 2015.12.
67. Masahiro Goto, Transdermal Cancer Immunization by a Surfactant-Coated Antigen Nanocarrier, ACB 2015, 2015.11.
68. Masahiro Goto, Transdermal Cancer Vaccine Using Antigen-Coating Nano Drug Carrier, AIChE 2015, 2015.11.
69. Wataru Yoshida, 後藤 雅宏, Extraction performance of novel amino acid derivative extractant for precious metal ions, 2015 Taiwan/Korea/Japan Joint Meeting on Chemical Engineering, 2015.11.
70. Yukiho Hosomomi, Masahiro Goto, Modification of E-coli cell surface for preparing a metal ion adsorbent, 2015 Taiwan/Korea/Japan Joint Meeting on Chemical Engineering, 2015.11.
71. Masato Sakuragi, Masahiro Goto, The melanoma prevention by transcutaneous cancer vaccine using Solid-in-Oil Technique, 2015 Taiwan/Korea/Japan Joint Meeting on Chemical Engineering, 2015.11.
72. Shota Araki, Masahiro Goto, Transdermal delivery of a vaccine antigen by the addition of ionic liquid, 2015 Taiwan/Korea/Japan Joint Meeting on Chemical Engineering, 2015.11.
73. Masahiro Goto, Ayaka Naritomi, Transcutaneous immunization using Solid-in-Oil nanodispersion with immunostimulatory adjuvants, 2015 Taiwan/Korea/Japan Joint Meeting on Chemical Engineering, 2015.11.
74. Masahiro Goto, Yukiho Hosomomi, Biosorption of rare earth elements by chemically modified E. coli, YABEC 2015, 2015.10.
75. Rie Wakabayashi, Masahiro Goto, Transglutaminase-mediated fabrication of multi-protein-labeled polyacrylamide for molecular biosensing, YABEC 2015, 2015.10.
76. Masahiro Goto, New Extractants Applicable to Industrial Solvent Extraction Processes for Critical Metal Separation, APCChE 2015, 2015.09.
77. 吉田航, 後藤 雅宏, Extraction of precious metals using novel amic acid-type extractant, 3rd International Symposium on Host Compounds for Separation and Functionality, 2015.07.
78. Masahiro Goto, Biocatalysis in Ionic Liquids, Southeast Asia Catalysis Conference 2015, 2015.05.
79. Masahiro Goto, Challenge to Commercialization of Advanced Drug Delivery Technology Developed in University, ICES Seminar, 2015.05.
80. Yoko Shin, Masahiro Goto, Development of transcutaneous pollinosis immunotherapy by using a solid-in-oil technique, The 27st International Symposium on Chemical Engineering, 2014.12.
81. Aya Naritomi, Masahiro Goto, Development of transcutaneous vaccine by Solid-in-Oil technology, The 27st International Symposium on Chemical Engineering, 2014.12.
82. Yuzo Baba, R.W. Cattrall, S.D. Kolev, Masahiro Goto, Development of polymer inclusion membrane with amide acid type extractant for separation of critical metals, 6th Int. Conf. Ion Exch., 2014 (ICIE 2014), 2014.11.
83. Yukiho Hosomomi, Masahiro Goto, Sorption properties of rare earth elements on chemically modified E. coli, 6th Int. Conf. Ion Exch., 2014 (ICIE 2014), 2014.11.
84. Yuzo Baba, R.W. Cattrall, S.D. Kolev, Masahiro Goto, Highly effective separation of scandium using a polymer inclusion membrane with an amide acid-type carrier, 10th Int. conf. Sep. Sci. Technol., 2014 (ICSST 14), 2014.11.
85. Masahiro GOTO, New extractants applicable to industrial solvent extraction process for rare metal separation, Int. Solv. Extrn. Cof., 2014, 2014.09.
86. Fukiko Kubota, Masahiro GOTO, Separation of rare earth metal ions by synergistic system with 2-thenoyltrifluoroacetone and TOPO, ISEC2014, 2014.09.
87. Tepei Niide, Masahiro Goto, Noriho Kamiya, Enzymatic fabrication of protein-gold nanoparticle conjugates by a one-pot, one-protein-component system, Korea-Japan Smart Biodesign Workshop: Technology exchane for green biotechnology, 2014.01.
88. Yuzo Baba, Masahiro Goto, Effective Separation and Recovery of Rare Earth Metals by Using Supported Ionic Liquid Membrane System, The 8th International Membrane Science & Technology Conference (IMSTEC2013), 2013.12.
89. Kosuke Moriyama, Masahiro Goto, Noriho Kamiya, In situ Hydrogel Formation Based on Tyramine Conjugated Linear Poly(ethylene glycol) via Enzymatic Oxidative Reaction, 25th Int. Symp. Chem. Eng., Kyushu(Japan)-Daejeon/Chungnam(Korea), 2013.12.
90. Yuya Hirakawa, Masahiro Goto, Development of transdermal cancer immunotherapy by using Solid-in-Oil nanodispersion
, The 26th International Symposium on Chemical Engineering, 2013.12.
91. Yukiho Hosomomi, Masahiro Goto, Chemical modification of E. coli for recovery of rare earth elements, 26th Int. Symp. Chem. Eng., Daejeon/Chungnam-Kyushu(Japan), 2013.12.
92. Masahiro Goto, Yusuke Tanaka, Transdermal delivery of salbutamol sulfate using a solid-in-oil nanodispersion, 26th Int. Symp. Chem. Eng., Daejeon/Chungnam-Kyushu(Japan), 2013.12.
93. Yoko Shin, Masahiro Goto, Transdermal pollinosis immunotherapy by a solid-in-oil nanodispersion, The 26th International Symposium on Chemical Engineering (ISChE 2013), 2013.12.
94. Masahiro Goto, Recycling of Rare Earth Metals by a Ionic Liquid Membrane, Critical Metal Recycle Symposium, 2013.11.
95. Masahiro Goto, Challenge to Commercialization of Advanced Technology in University, Japan-Korea-Taiwan Joint Chemical Engineering Symp., 2013.11.
96. Masahiro Goto, Directed Aggregation and Fusion of vesicles induced by a DNA surfactant, AIChE Annual Meeting, 2013,, 2013.11.
97. Masahiro Goto, Nanodispersion of Pharmaceutical Ingredients for Transdermal Drug Delivery Systems, INCHEM TOKYO, 2013.10.
98. Teppei Niide, Masahiro Goto, Noriho Kamiya, Enzymatic Synthesis of Protein-Gold Nanoparticle Conjugates: Stable Immobilization by Artificial Peptide-Tag for Gold Surface, Enzyme Engineering XXII Conference, 2013.09.
99. Rie Wakabayashi, Masahiro Goto, Nanostructured Peptide Amphiphiles for Supramolecular Biomaterials, New Trends of Nano- or Bio-Materials Design in Supramolecular Chemistry (2013 NNBS), 2013.09.
100. Yukiho Hosomomi, Masahiro Goto, Development of bacterial biosorbent for rare earth elements, International Symposium on Cell Surface Structures and Functions, 2013.09.
101. Teppei Niide, Masahiro Goto, Noriho Kamiya, Biocatalytic Synthesis of Protein-Decorated Gold Nanoparticles, The 19th Symposium of Young Asian Biochemical Engineers' Community (YABEC 2013), 2013.08.
102. Jian Yang, Masahiro Goto, Development of Membrane Separation System for Rare Metals Based on Ionic Liquids, Conference of Aseanian Membrane Society(AMS8), 2013.07.
103. Fukiko Kubota, Masahiro Goto, Selective Transport of Rare Earth Metals through a Supported Liquid Membrane Using Ionic Liquids, Conference of Aseanian Membrane Society(AMS8), 2013.07.
104. Rie Wakabayashi, Masahiro Goto, Nanostructured Peptide Amphiphile Assemblies for Bioactivity Control, 8th International Symposium on Macrocyclic and Supramolecular Chemistry (8-ISMSC), 2013.07.
105. Masahiro Goto, Directed aggregation and fusion of vesicles induced by a DNA-surfactant, Liaison Functions 2013 - Core Programming Area at the 2013 AIChE Annual Meeting: Global Challenges for Engineering a Sustainable Future, 2013.
106. Teppei Niide, Masahiro Goto, Noriho Kamiya, One-pot fabrication of protein-gold nanoparticle conjugate by enzymatic reaction, The 25th International Symposium on Chemical Engineering, 2012.12.
107. Yuko Abe, Noriho Kamiya, Masahiro Goto, Development of pH-sensitive double coating carrier for intracellular drug delivery
, The 25th International Symposium on Chemical Engineering, 2012.12.
108. Yutaro Mori, Masahiro Goto, Noriho Kamiya, Development of a novel acetamide-type extractant for cobalt recycling process, The 25th International Symposium on Chemical Engineering, 2012.12.
109. Jian Yang, Fukiko Kubota, Masahiro Goto, Separation of precious metals by using ion-exchange polymers, The 25th International Symposium on Chemical Engineering, 2012.12.
110. Kosuke Moriyama, Masahiro Goto, Noriho Kamiya, Horseradish peroxidase-mediated fabrication of a polymer-protein hybrid hydrogel, The 25th International Symposium on Chemical Engineering, 2012.12.
111. Ryutaro Ishiyama, Masahiro Goto, A novel double-coating carrier for cancer-targeted drug delivery, The 25th International Symposium on Chemical Engineering, 2012.12.
112. Kana Imamura, Noriho Kamiya, Masahiro Goto, Development of transcutaneous vaccine formulation using Solid-in-Oil technology, The 25th International Symposium on Chemical Engineering, 2012.12.
113. Yusuke Tanaka, Masahiro Goto, Transdermal delivery of salbutamol sulfate by a solid-in-oil nanodispersion, The 25th International Symposium on Chemical Engineering, 2012.12.
114. Yukiho Hosomomi, Fukiko Kubota, Masahiro Goto, Biosorption of rare earth elements onto E. coli, The 25th International Symposium on Chemical Engineering, 2012.12.
115. Teppei Niide, Masahiro Goto, Noriho Kamiya, Enzymatic production of functional protein-gold nanoparticles conjugates, The 25th International Symposium on Chemical Engineering, 2012.12.
116. Teppei NIide, Masahiro Goto, Noriho Kamiya, Enzymatic approach for synthesis of protein-gold nanoparticle conjugates, The 18th Symposium of Young Asian Biochemical Engineers' Community, 2012.10.
117. Uju, Masahiro Goto, Noriho Kamiya, Pyridinium ionic liquids as pretreatment agents for enhancing enzymatic saccharification of cellulosic biomass, 2012 Lignobiotch II symposium, 2012.10.
118. Hiroki Abe, Masahiro Goto, Noriho Kamiya, Lipid Modification of Proteins Catalyzed by Transglutaminase, 2nd International Conference on Molecular & Functional Catalysis (ICMFC-2), 2012.07.
119. Ionic Liquids and Bioscience .
120. Yutaro Mori, Masahiro Goto, Noriho Kamiya, Functional protein assemblies by site-specific avidin-biotin interactions, 12th Japan-China-Korea Joint Symposium on Enzyme Engineering, 2012.05.
121. Separation of Rare Earth Metals by Using Ionic Liquids.
122. Masahiro Goto, A nanostructured molecular assembly in ionic liquids as a novel medium for biocatalysis reactions, 2008 AIChE Annual Meeting, AIChE 100, 2008.
123. Masahiro Goto, Kojiro Shimojo, Kazunori Nakashima, Solubilization and functional changes of biomolecules in ionic liquids, 55th Society of Polymer Science Japan Symposium on Macromolecules, 2006, This lecture reports on the protein transfer from an aqueous phase into ionic liquids (ILs) with dicyclohexano-18-crown-6 (DCH18C6), and the functional change of cytochrome c (Cyt-c) dissolved in ILs. Further, a protein is modified with comb-shaped poly (ethylene glycol), PM13. PM13 modified subtilisin (PM13-Sub) could be solubilized clearly in a wide range of pure ILs. This markedly high activity in the IL was superior to that in organic solvents commonly used for enzymatic catalysis. PM13-Sub was also found to retain its catalytic activity in the ILs for a prolonged period..
124. Mai Hiraki, Tatsuo Maruyama, Hiroshi Yamamura, Masahiro Goto, Aggregation of DNA-tagged liposomes controllable by external stimuli, 54th SPSJ Annual Meeting 2005, 2005, Here we describe a novel strategy of liposome aggregation employing DNA-surfactant, in which the aggregation of liposomes can be reversibly controlled by enzyme stimuli and temperature. Single-stranded oligonucleotides were tethered to the outer surface of liposomes. Mixing of the DNA-tagged liposomes with ones bearing complementary DNA strands initiated the aggregation of liposomes. The liposomes were linked with each other via duplex DNA. The aggregated liposomes were dissociated by restriction enzyme to produce the initial discrete liposomes and re-aggregated by ligase..
125. Masahiro Goto, Kazunori Nakashima, Comb-shaped polyethylene glycol-modifled subtilisin soluble and highly active in ionic liquids, 05AIChE: 2005 AIChE Annual Meeting and Fall Showcase, 2005, Subtilisin Carlsberg conjugated with comb-shaped polyethylene glycol was solubilized in common ionic liquids without adding water, and exhibited higher transesterification activity in ionic liquids than in organic solvents commonly used for enzymatic biotransformation. Many researchers are becoming increasingly interested in the application of ILs as reaction media for biotransformation. Recent works showed that enzymes exhibited their catalytic activities in pure ILs or IL/aqueous biphasic systems, providing many advantages such as high conversion rates, high enantioselectivity, and increased stability of enzymes. However, one of the most significant limitations in enzymatic reactions in ILs is the relatively low activity of enzymes suspended in ILs. Some ILs are known to dissolve enzymes with or without a small amount of water, however, dissolved enzymes show little catalytic activity presumably due to their conformational change in ILs. To overcome this limitation, several studies have been conducted to enhance enzymatic activity in ILs, involving the addition of a small amount of water to ILs, and immobilization of enzyme with solid supports. Polyethylene glycol (PEG) shows high solubility in ILs, and was found to provide high stability and dispersibility of enzymes in ILs. We previously showed the effective activation of lipases in ILs by physical complexation of lipases with PEG 20,000. Although some researchers attempted to improve solubility and activity of enzymes in ILs by covalent modification with PEG, chemical modification of enzymes with linear PEG did not offer sufficient solubility and catalytic activity in ILs. Here, we report the use of comb-shaped PEG as an enzyme modifier to solubilize an enzyme in ILs. Comb-shaped PEG, PM13 is a copolymer derivative of PEG and maleic anhydride with an approximate molecular weight of 13,000 and has multivalent reactive sites, acid anhydrides, which react preferentially with amino groups in a protein molecule. The potential utility of PM13 was validated in enzymatic catalysis in organic solvents. In the present study, we have demonstrated perfect solubilization and marked enhancement of catalytic activity of an enzyme in ILs by modification with PM13. To our knowledge, this great superiority of enzymatic catalysis in pure ILs compared with organic solvents has not yet been reported. In summary, we showed that comb-shaped PEG, PM13, is an excellent modifier to solubilize enzymes in ILs. This approach offers high enzymatic activity in pure ILs without immobilization of enzyme or addition of small amounts of water. We believe that this paper will stimulate researchers to develop further applications in the field of enzymology for the use of ILs..
126. Kazunori Nakashima, Tatsuo Maruyama, Noriho Kamiya, Masahiro Goto, Solubilization and high activity of enzymes in ionic liquids by modification with comb-shaped poly (ethylene glycol), 54th SPSJ Symposium on Macromolecules, 2005, Subtilisin Carlsberg was modified with comb-shaped poly (ethylene glycol), PM13. PM13 modified subtilisin (PM13-Sub) could be solubilized clearly in a wide range of pure ILs, whereas native subtilisin was not soluble in any ILs. Furthermore, PM13-Sub dissolved in ILs exhibited the excellent catalytic activity in transesterification of N-acetyl-L-phenylalanine ethyl ester with 1-butanol. This markedly high activity in the IL was superior to that in organic solvents commonly used for enzymatic catalysis. PM13-Sub was also found to retain its catalytic activity in the ILs for a prolonged period..
127. Tatsuo Maruyama, Mai Hiraki, Hiroshi Yamamura, Harumi Takata, Masahiro Goto, Stimuli-responsive liposome aggregation induced by DNA-surfactants, 54th SPSJ Symposium on Macromolecules, 2005, Here we describe a novel strategy of liposome aggregation employing DNA-surfactant, in which the aggregation of liposomes can be reversibly controlled by enzyme stimuli and temperature. Single-stranded oligonucleotides (24-mer) were bound to oleic acid to produce DNA-surfactant. The DNA surfactant was mixed with POPC liposomes to prepare DNA-tethered liposomes. Mixing of the DNA-tagged liposomes with ones bearing complementary DNA strands starts the aggregation of liposomes. The liposomes were linked with each other via duplex DNA. We found that the liposome aggregation was influenced by temperature, salt concentration and restriction enzyme..
128. Masahiro Goto, Tatsuo Maruyama, Noriho Kamiya, Poly(ethylene glycol)-lipase complex highly active in ionic liquids, 2004 AIChE Annual Meeting, 2004, The alcoholysis catalyzed by the poly(ethylene glycol) (PEG)-lipase complex in ionic liquids was investigated. The alcoholysis between vinyl cinnamete and benzyl alcohol was catalyzed by lyophilized native lipase PS or the PEG-lipase PS complex in [Hmin][PF6]. The alcoholysis reaction involves acylation of the lipase and esterification of benzyl alcohol. The results show that the differences in activation among lipases was related to the solvent tolerance of the lipase or the dispersion of the PEG-lipase complexes..
129. Novel Function by combining nanotechnology and biotechnology.
130. Past and future on solvent extraction of biomolecules.
131. Hiroyuki Wariishi, H. Tanaka, Masahiro Goto, S. Furusaki, Nonaqueous biotechnology utilizing organic solvents tolerant ligninolytic enzymes, 68th Pulp and Paper Research Conference 2001, 2001, Lignin-degrading basidiomycetes have been known to secrete ligninolytic enzymes such as lignin and manganese peroxidases (LiP and MnP) and laccase. Since these enzymes play an important role in fungal metabolism of environmentally persistent aromatic compounds, including water-insoluble dioxin and biphenyl derivatives, we attempted to utilize them in nonaqueous media. Although these enzymes catalyze one-electron oxidation reactions, their electron transfer mechanisms are not the same. Therefore, the optimal method for each ligninolytic enzymes to utilize in organic media is different. To obtain stable ligninolytic activities in organic media, a peptide-hydrolyzed cytochrome c (microperoxidase-11), a dendritic porphyrin, and surfactant-coated MnP and laccase were prepared. Microperoxidase-11 was very stable in water miscible solvents such as methanol and ethanol, showing MnP activity as well as a peroxidase activity. The dendritic porphyrin oxidized both veratryl alcohol and 2, 6-dimethoxyphenol in benzene and chloroform. To obtain MnP and laccase complexes with surfactant molecules, a novel preparation method utilizing water-in-oil emulsions has been developed. LiP exhibited stable activity in isooctane when it was encapsulated in a reversed micelle..
132. Hiroyuki Wariishi, Mari Kabuto, Takeshi Yamanaka, Shinya Okazaki, Masahiro Goto, Hiroo Tanaka, Ligninolytic activities in non-aqueous media, Proceedings of the 1998 7th International Conference on Biotechnology in the Pulp and Paper Industry. Part 1 (of 3), 1998, To obtain stable ligninolytic activities in organic media, a peptide-hydrolyzed cytochrome c (microperoxidase-11), a dendritic porphyrin, and a surfactant-coated MnP (MnP complex) were prepared. Microperoxidase-11 was very stable in water miscible solvents such as methanol and ethanol, showing MnP activity as well as peroxidase activity. The dendritic porphyrin oxidized either veratryl alcohol or 2, 6-dimethoxyphenol in benzene and chloroform. MnP complex was soluble in dry benzene where it catalyzed MnII-dependent oxidation of a series of aromatic substrates..