| 1. |
@Yoshiko Miura, De Novo designed glycopolymers, ISBOC-13, 2023.12. |
| 2. |
#Haruka Shiomitsu、@Takato Ishida、@Hikaru Matsumoto、@Masanori Nagao、@Yoshiko Miura, Anti-inflammatory effect in macrophage-like cells with sialy oligosaccharide carrying star glycopolymers, ISBOC-13, 2023.12. |
| 3. |
@Y.Miura,@H.Matsumoto,@M.Nagao,, Catalyst immobilized polymer monolith for continuous flow synthesis, C&FC2023, 2023.12. |
| 4. |
@Masanori Nagao、@Yoshiko Miura, Topological Design of Star Glycopolymers for Controlling the Interactions with the Influenza virus, CSChE2023 CALGARY, 2023.10. |
| 5. |
#Harutaka Shigeeda、@Masanori Nagao、@Yoshiko Miura, Organic Synthesis by Polymer Monoliths with Immobilised Organocatalysts, 20thAPCChE Congress, 2023.09. |
| 6. |
#Shota Furusawa、@Masanori Nagao、@Yoshiko Miura, Photoreduction of CO2 by monoliths incorporating iron porphyrins, 20thAPCChE Congress, 2023.09. |
| 7. |
Shota Iseri, Sotaro Akashi, Yusuke Saito, Hinako Iwamoto, Masanori Nagao, Yu Hoshino, Yoshiko Miura, A multifunctional diblock oligomer with a completely uniform steric structure that recognizes peptides, 第71回高分子学会年次大会, 2022.05. |
| 8. |
Yoshiko Miura, Seiya Nonaka, Hikaru Matsumoto, Tomoki Imoto, Masanori Nagao, Yu Hoshino, Continuous flow synthesis process with polymer immobilized organo catalyst of polymer monolith, 第71回高分子学会年次大会, 2022.05. |
| 9. |
Yoshiko Miura, Denovo design of glycopolymer for controlled molecular recognition, Pacific Polymer Conference 17 (PPC17), 2022.12. |
| 10. |
W.Jin, M. Nagao,Y. Miura, Synthesis of cyclic glycopolymers and evaluation of the interaction with target proteins, Pacific Polymer Conference 17 (PPC17), 2022.12. |
| 11. |
T. Ishida, M. Nagao, H. Ise, Y. Miura, Investigation of the anti-inflammatory effect in macrophage-like cells using glycopolymers bearing sialyloligosaccharides, Pacific Polymer Conference 17 (PPC17), 2022.12. |
| 12. |
Y.Miura, De Novo Designed Glycopolymer via Living Radical Polymerization, Pacificpolymer Conference, 2019.12. |
| 13. |
Y.kimoto,Y.Terada,Y.Hoshino,Y.Miura, Screening Glycopolymer with HydrophobicGroups for Detection of Cholera Toxin, Pacific polymer Conference, 2019.12. |
| 14. |
M.Kichize,Y.Miura,Y.Hoshino, Precise Synthesis of Glycopolymer and Its Function, Pacific polymer Conference, 2019.12. |
| 15. |
K.Nobuhiro,S.Aki,Y.Hoshino,Y.Miura, Study of Cell Separation Method Basedon Size and Deformability Using Metal Mesh Device, 2019 JTK conference, 2019.11. |
| 16. |
H.Takimoto,S.Taniguchi,Y.Hoshino,Y.Miura, Preparation of Oligomer LigandNeutralizing Toxicity of Target Peptide via Aqueous Phase Radical Polymerization, 2019 JTK conference, 2019.11. |
| 17. |
H.Matsumoto,Y.Hoshino,T.Iwai,M.Sawamura,Y.Miura, Polystyrene-Phosphine Monolithfor Transition-Metal Catalysis in Flow Synthesis, SKYsymposium, 2019.11. |
| 18. |
Yoshiko Miura, Denovo Design of Glycopolymer, 九州・西部-釜山・慶南 高分子(第19回)繊維(第17回)合同シンポジウム, 2019.11. |
| 19. |
Yida Liu、安藝 翔馬、今村 和史、三浦 佳子、星野 友, Micro imprinting of polymeric membraneby direct short pulsed laser, 第68回高分子討論会, 2019.09. |
| 20. |
K.Nobuhiro,S.Aki,Y.Hoshino,Y.Miura, Cell separation with metal mesh device, APCChE2019, 2019.09. |
| 21. |
Haruka Hattori,H.Matsumoto,Y.Hoshino,Y.Miura, Development of MacroporousPolymer Monolith lmmobilized L-Proline-Based Organocatalyst and Applicationto Flow Asymmetric Aldol Addition Reaction, APCChE2019, 2019.09. |
| 22. |
Kota,Katafuchi,Y.Terayama,J.Matsuda,G.Inoue,Y.Miura,Y.Hoshino, Effects offiller characteristics for CO2 capture kinetic by aeroporpus hydrogel film, APCChE2019, 2019.09. |
| 23. |
H.Matsumoto,Y.Hoshino,T.Iwai,M.Sawamura,Y.Miura, Transition-metal catalysisin flow system using biphasic solvent:Macroporous polystyrene supportingpalladium-phosphine complex, APCChE2019, 2019.09. |
| 24. |
S.Aki,K.Nobuhiro,Y.Hoshino,Y.Miura, Separation of blood cells using MetalMesh device, APCChE2019, 2019.09. |
| 25. |
Y.Terayama,K.Katafuchi,J.Matsuda,G.Inoue,Y.Miura,Y.Hoshino, Separated Gas-WaterPhases Structure of Aeroporous Hydrogel Film for CO2 Capture under HumidCondition, APCChE2019, 2019.09. |
| 26. |
Y.miura, H.Seto, M.Shibuya, Y.Hoshino, Biopolymer monolith for protein separation, Nanolithography of Biointerfaces Faraday Discussion, 2019.07, Porous glycopolymers, “glycomonoliths”, were prepared by radical polymerization based on polymerization-induced phase separation with an acrylamide derivative of α-mannose, acrylamide and cross-linker in order to investigate protein adsorption and separation. The porous structure was induced by a porogenic alcohol. The pore diameter and surface area were controlled by the type of alcohol. The protein adsorption was measured in both batch and continuous flow systems. The glycomonoliths showed specific interaction with the sugar recognition protein of concanavalin A, and non-specific interaction to other proteins was negligible. The amount of protein adsorption to the materials was determined by the sugar density and the composition of the glycomonoliths. Fundamental knowledge regarding the glycomonoliths for protein separation was obtained.. |
| 27. |
H.Matsumoto,Y.Hoshino,T.Iwai,M.Sawamura,Y.Miura, Application of MacroporousPolystyrene-Triphenylphosphine Monolith to Palladium-Catalyzed Cross-CouplingReaction in Flow System, ISPC2019, 2019.07. |
| 28. |
Yoshiko Miura, Hirokazu Seto, Makoto Shibuya, Yu Hoshino, Glycopolymer monolith for protein separation, Faraday Discussion, 2019.07. |
| 29. |
Yoshiko Miura,Hirokazu Seto,Makoto Shibuya, Yu Hoshino, Biopolymer monolith for protein separation, Faraday Discussion, 2019.07, Porous glycopolymers, “glycomonoliths”, were prepared by radical polymerization based on polymerization-induced phase separation with an acrylamide derivative of α-mannose, acrylamide and cross-linker in order to investigate protein adsorption and separation. The porous structure was induced by a porogenic alcohol. The pore diameter and surface area were controlled by the type of alcohol. The protein adsorption was measured in both batch and continuous flow systems. The glycomonoliths showed specific interaction with the sugar recognition protein of concanavalin A, and non-specific interaction to other proteins was negligible. The amount of protein adsorption to the materials was determined by the sugar density and the composition of the glycomonoliths. Fundamental knowledge regarding the glycomonoliths for protein separation was obtained.. |
| 30. |
Takahiro Oh、Yu Hoshino、Yoshiko Miura, The effect of the glycopolymer lengthon the self-assembly of double-hydrophilic block glycopolymer, 第68回高分子学会年次大会, 2019.05. |
| 31. |
H. Hattori, H. Matsumoto, Y. Hoshino, Y. Miura, Development of macroporous polymer monolith containning L-proline-based organocatalyst and application to flow asymmetric aldol addition reaction, ISChE2018, 2018.12. |
| 32. |
H. Takimoto, S. Taniguchi, Y. Hoshino, Y. Miura, Development of polymer ligand for recognation of target toxic peptide, ISChE2018, 2018.12. |
| 33. |
K.Jono,S.Sonoda,M.Nagao,Y.Hoshino,Y.Miura, the molecular recognition of glycopolymers via distance arrangement of sugar blocks, IUPAC macro, 2018.07. |
| 34. |
M.Nagao,Y.Fujiwara,T.Matsubara,@Y.Hoshino,T.Sato,@Y.Miura, Design of Glycopolymers Carrying Sialyl Oligosaccharides and the Interaction with the Influenza Virus, IUPAC macro, 2018.07. |
| 35. |
Y.Miura,K.Jono,M.Nagao, Denovo Design of Glycopolymer, IUPAC macro, 2018.07. |
| 36. |
Y.Miura,H.Matsumoto,M.Shibuya, Polymer Gel for Biomimetic Reactor, IUPAC macro, 2018.07. |
| 37. |
M.Moribe,N.Gondo,M.Nakamoto,Y.Hoshino,Y.Miura, Increase of reversible salt absorption capacity of temperature-responsive hydrogel film consisting of nanogel particles, IUPAC macro, 2018.07. |
| 38. |
三浦 佳子, Glycopolymer monolith for protein separation
, ACS National Meeting, 2017.04. |
| 39. |
Yoshiko Miura, Porous Glycopolymer Monolith for Protein Separation
, Ewha Chemistry and Nanoscience International Symposium (ECNIS) 2016, 2016.10. |
| 40. |
Yoshiko Miura, Glycosaminoglycan Mimimetic Polymer for Nanomedicine
, Nanomedicine 2016, 2016.08. |
| 41. |
三浦 佳子, Glyco-Polymer Monolith for Protein Separation
, Nanokorea, 2016.07. |
| 42. |
Masanori Nagao, Hirokazu Seto, Tomonari Tanaka, T. Tahakashi, T. Suzuki, Yu Hoshino, Yoshiko Miura, Synthesis of influenza virus-recognizing glycopolymer via RAFT polymerization and Copper-Catalyzed Azide-Alkyne Cycloaddition, Pacifichem, 2015.12. |
| 43. |
Xinnan Cui, Yuki Koujima, Yu Hoshino, Hirokazu Seto, Yoshiko Miura, MiuraInhibition of bacteria adhesion and protein adsorption on hydroxyapatite surface using PEG-Phosmer copolymers, Pacifichem, 2015.12. |
| 44. |
Masanori Nagao, Takahiro Oh, Hirokazu Seto, Tomonari Tanaka, T. Tahakashi, T. Suzuki, Yu Hoshino, Yoshiko Miura, Synthesis of well-defined glycopolymers bearing oligosaccharide using post-click chemistr, 7th Asian Community of Glycoscience Glycotechnoloty, 2015.11. |
| 45. |
Yoshiko Miura, Biosensing with Glycopolymer-Gold Conjugates, 7th Asian Community of Glycoscience Glycotechnoloty, 2015.11. |
| 46. |
Yoshiko Miura, Preparation of glyco-nanomaterials via RAFT living radical polymerization and application for biosensing, ACS national meeting, 2015.08. |
| 47. |
三浦 佳子, Glycopolymer nanomedicine with glcosaminoglycan mimetics, IUMRS-ICMAT2015, 2015.06. |
| 48. |
Yoshiko Miura, Xinnan Cui, 國府島 由紀, 瀬戸 弘一, 星野 友, Inhibition of Biofilm Adhesion on Hydroxyapatite Surface by Using PEG-Phosmer Copolymer
, 第64回高分子学会年次大会, 2015.05. |
| 49. |
Xinnan Cui, 國府島 由紀, 瀬戸 弘一, 星野 友, 三浦 佳子, Inhibition of Biofilm Adhesion on Hydroxyapatite Surface by Using PEG-Phosmer Copolymer, 第64回高分子学会年次大会, 2015.05. |
| 50. |
長尾 匡憲, 瀬戸弘一, 田中知成, 星野 友, 三浦 佳子, RAFT Linving radical polymerization of glycopolymers having various polymer backbones, and molecular recognition, 高分子学会年次大会, 2015.05. |
| 51. |
小丸 香奈恵, 飯島 一智, 星野 友, 三浦 佳子, 橋詰 峰雄, 擬似体液中でのリン酸カルシウムのミネラリゼーションにおけるカルボキシ基を有する高分子ナノ粒子の影響, 第64回高分子学会年次大会, 2015.05. |
| 52. |
Xinnan Cui, 瀬戸 弘一, 星野 友, 三浦 佳子, Inhibition of Biofilm Adhesion on Hydroxyapatite Surface by Using PEG-Phosmer Copolymer
, 第24回日本MRS年次大会, 2014.12. |
| 53. |
米田玉弥, 森井崇人, 瀬戸 弘一, 星野 友, 三浦佳子, Pd-supported polymer nanoparticle immobilized silica membrane type reactor
, The 27th International Symposium on Chemical Engineering, 2014.12. |
| 54. |
國府島由紀, 瀬戸 弘一, 星野 友, Yoshiko Miura, Inhibition of protein and bacteria adsorption on hydroxyapatite surface
, The 27th international symposium on chemical engineering, 2014.12. |
| 55. |
Yoshiko Miura, 星野 友, KAORU TAMADA, 瀬戸 弘一, Shuhei Shinohra, 寺田侑平, Analysis of glycopolymer-brush structure on gold substrate using SPP spectroscopy
, The 7th International Symposium on Surface Science, 2014.11. |
| 56. |
Yue Mengchen, 星野 友, 三浦 佳子, Detail study about the thermo-responsive microgel particles as CO2 absorbents, 第46回化学工学会 秋季大会, 2014.09. |
| 57. |
三浦 佳子, 星野 友, 大橋良平, Preparation of Temperature Responsive Nanogels with Carboxylic Acids which Undergo Large and Reversible pKa Shift, IUMRS-International Conference on Electronic Materials (IUMRS-ICEM 2014), 2014.08. |
| 58. |
星野 友, 大橋 良平, 三浦 佳子, Development of Enzyme-Mimic Proton Transfer Systems, IUMRS-International Conference on Electronic Materials (IUMRS-ICEM 2014), 2014.08. |
| 59. |
Haejoo Lee, Yusuke Wada, 星野 友, 三浦 佳子, Study of Synthetic Polymer Ligands as Plastic Antibody, IUMRS-International Conference on Electronic Materials (IUMRS-ICEM 2014), 2014.08. |
| 60. |
國府島 由紀, 瀬戸弘一, 星野 友, 三浦佳子, Biomacromolecular adsorption on oligoethyleneglycol modified dendrimer interfaces, IUMRS-ICA2014, 2014.08. |
| 61. |
Hiroyuki Koide, 星野 友, Yuri Nishimura, 三浦 佳子, Naoto Oku, Kenneth Shea, Synthetic polymer nanoparticle with engineered affinity for a vascular endothelial growth factor , 248th ACS National Meeting, 2014.08. |
| 62. |
Hiroyuki Koide, 星野 友, Yuri Nishimura, 三浦 佳子, Naoto Oku, Kenneth Shea, Synthetic polymer nanoparticle with engineered affinity for a vascular endothelial growth factor , 248th ACS National Meeting, 2014.08. |
| 63. |
星野 友, 大橋 良平, 三浦 佳子, Development of liquid membranes consisting of aqueous solution of proton-imprinted nanogel particles for heat-induced ion separation, 248th ACS National Meeting, 2014.08. |
| 64. |
Xinnan Cui, 瀬戸 弘一, 星野 友, 三浦 佳子, Inhibition of Biofilm Adhesion on Hydroxyapatite Surface by Using PEG-Phosmer Copolymer, 第二十五回九州地区若手ケミカルエンジニア討論会, 2014.07. |
| 65. |
三浦 佳子, Glycopolymer Interface, CC3DMR2014, 2014.06. |
| 66. |
三浦 佳子, Glycopolymer Coated Gold Nanoparticle via RAFT Polymerization for Biosensing
, CIMTEC2015, 2014.06. |
| 67. |
三浦 佳子, Haejoo Lee, 和田 悠佑, 星野 友, Design of synthetic polymer ligands that recognize and capture target peptides with multipoint interactions, Polymers and Organic chemistry 2014 (POC2014), 2014.06. |
| 68. |
星野 友, 大橋亮平, 三浦 佳子, Preparation of Proton Imprinted Nanoparticles with Switchable pKa Values: Toward Plastic Enzymes, MRS Fall Meeting, 2013.12. |
| 69. |
三浦 佳子, Glyco-Interface for Biosensing, The 4th Asian Symposium on Advanced Materials – Chemistry, Physics & Biomedicine of Functional and Novel Materials, 2013.10. |
| 70. |
LEE HAEJOO, YUSUKE WADA, 星野 友, 三浦 佳子, The first step for synthetic antibody: Minization of synthetic antibodies that recognize and capture targeted peptide, バイオ高分子シンポジウム, 2013.07. |
| 71. |
三浦 佳子, Glycopolymer Interface for Bio-Functional Materials
, Collaborative Conference on 3D & Materials Research, 2013.06. |
| 72. |
Mengchen Yue, Yu Hoshino, Yoshiko Miura, Preparation of Hydrogel Films Consisting of Amine-containing Nano-gel Particles and Evaluation of
their CO2 Absorption Properties
, 高分子学会, 2013.05. |
| 73. |
Yuhei Terada, Tatsuro Endo, 瀬戸 弘一, Yu Hoshino, Yoshiko Miura, Structural-color Biosensor Immobilized with Sugar-incorporating Nanoparticles
, 高分子学会, 2013.05. |
| 74. |
三浦 佳子, 國府島 由紀, 瀬戸 弘一, 星野 友, Molecular Recognition of Proteins and Bacteria on the Dendrimer Interface
, 高分子学会, 2013.05. |
| 75. |
Formation of Dendrimer Surface and Analysis of Protein Adsorption. |
| 76. |
The explanation of the propose of session of Soft Material Interface . |
