| 1. |
Qi Li, Mayumi Hatakeyama, Takuya Kitaoka, Nanofiber-Stabilized Pickering Emulsions Induce Pyroptosis in Kupffer Cells, 九州大学超顕微解析研究センター報告, 47, 38-39, 2023.08. |
| 2. |
Dani Permana, Takuya Kitaoka, Hirofumi Ichinose, Conversion and synthesis of chemicals catalyzed by fungal cytochrome P450 monooxygenases: A review, Biotechnology and Bioengineering, 10.1002/bit.28411, Volume120, Issue7
July 2023
Pages 1725-1745, 2023.05. |
| 3. |
Functional design of bioadaptive cell culture scaffolds regulated by structural polysaccharide nanofibers. |
| 4. |
Takuya Kitaoka, Emerging Functions of Nano-Organized Polysaccharides, Nanomaterials, 10.3390/nano12081277, 12(8), 1277 (2022), 2022.04.  |
| 5. |
Creating new values of cellulose nanofibers. |
| 6. |
Biofunction of cell culture scaffolds triggered by polysaccharide nanofibers. |
| 7. |
Kojiro Uetani, Naliharifetra Jessica Ranaivoarimanana, Mayumi Hatakeyama, Takuya Kitaoka, Inherently Distinctive Potentialities and Uses of Nanocellulose Based on its Nanoarchitecture, BioResources, 2021.03. |
| 8. |
Kojiro Uetani, Takuya Kitaoka, Nanocellulose: Beyond the Ordinary, BioResources, 16(1), 1-4 (2021), 2020.11. |
| 9. |
Lignification-inspired Biomimetic Surface Modification of Wood Nanocellulose
N. Fukuda, K. Kanomata, T. Kitaoka. |
| 10. |
Interfacial Design of Glyco-nanolayers for Cell Adhesion. |
| 11. |
Knoevenagel condensation by chitosan nanofibers
Y. Hirayama, K. Kanomata, T. Kitaoka. |
| 12. |
Interfacial Catalysis via Cellulose Nanofibers. |
| 13. |
Interfacial Acid Hydrolysis of Acetals by Surface-carboxylated Nanocellulose
Y. Tamura, K. Kanomata, T. Kitaoka. |
| 14. |
New Frontier of Paper-structured Catalysts. |
| 15. |
Fischer-Tropsch Synthesis over Paper-Structured Catalysts
A. Saimura, T. Kitaoka. |
| 16. |
Materials Design Inspired by Paper and Cellulose Architectures. |
| 17. |
Structural and functional design of cellulose nanomaterials. |
| 18. |
Microflow Chemical Synthesis over Stacked Paper-Structured Catalysts
Y. Ishihara, T. Kitaoka. |
| 19. |
Cooperative catalysis by the combination of TEMPO-oxidized cellulose nanofibers and proline. |
| 20. |
Emergent Functions of Nanocellulose Hybrid Materials
T. Kitaoka
Nanofiber
. |
| 21. |
Sequential Desulfurization and Methane Steam Reforming by Paper-Structured Catalysts
A. Saimura, Y. Shiratori, T. Kitaoka. |
| 22. |
Cellulose Materials Innovation. |
| 23. |
Blue Ocean Strategy in Wood Science and Industries. |
| 24. |
Hirotaka Koga, Takuya Kitaoka, Akira Isogai, Chemically-modified cellulose paper as a microstructured catalytic reactor, Molecules, 20, 1495-1508 , 2015.01. |
| 25. |
Selective Gas Separation by Hybrid Nanofilms of Cellulose and Metal-organic Frameworks
M. Matsumoto, T. Kitaoka. |
| 26. |
Emerging Issues for Paper Materials
T. Kitaoka
Sen'i Gakkaishi, 70(9), P430-P433 (2014)
The Society of Fiber Science and Technology, Japan. |
| 27. |
Introduction of Laboratory of Bioresources Chemistry, Kyushu University
T. Kitaoka
Kamipa Gikyoushi, 68(8), 80-81/914-915 (2014)
Japan TAPPI. |
| 28. |
Functional Nano-Architectonics of Glyco-Biointerfaces
T. Kitaoka
Cellulose Communications, 20(2), 63-68 (2013)
The Cellulose Society of Japan. |
| 29. |
Paper-like Catalysts for Environmental, Energy, Chemical and Biological Applications
Takuya Kitaoka
Journal of Packaging Science & Technology, Japan. |
| 30. |
Structural and Functional Design of Cellulosic Nanohybrid Materials
T. Kitaoka
Nanofiber
. |
| 31. |
Koga H., Kitaoka T., On-paper synthesis of metal nanoparticles for catalytic applications, Sen'i Gakkaishi, 67(7), 141-152, 2011.07. |
| 32. |
Kitaoka T., Yokota S., Opietnik M., Rosenau T., Synthesis and bio-applications of carbohydrate-gold nanoconjugates with nanoparticle and nanolayer forms, Materials Science and Engineering C: Materials for Biological Applications, 31(6), 1221-1229, 2011.08. |
| 33. |
Development and Applications of Paper-Structured Catalysts
T. Kitaoka
THE GLOBE. |
| 34. |
Advanced Material Design and Applications of Cellulose
T. Kitaoka
Kobunshi, High Polymers. |
| 35. |
Architectural Design and Functional Development of Cellulosic Nanolayers
T. Kitaoka, S. Yokota
Bioscience & Industry. |
| 36. |
A Novel Conception for the Wet-End Interactions Based on the Molecular Recognition on Paper Surface
T. Kitaoka
Wood Science in Kyushu, 13(1), 3-6 (2006). |
| 37. |
Development of Porous Catalyst/Fiber Composites by a Papermaking Technique
A. Tomoda, R. Suzuki, T. Kitaoka
Fuel Cell, 5(4), 83-87 (2006). |
| 38. |
Wet-End Interaction Based on the Molecular Recognition at the Cellulose/Water Interface
T. Kitaoka
Report of the Center of Advanced Instrumental Analysis Kyushu University, 23, 15-24 (2005). |
| 39. |
Catalyst Paper
T. Kitaoka
Sen'i Gakkaishi, 60(9), P439-P442 (2004)
The Society of Fiber Science and Technology, Japan. |
| 40. |
Paperlike fiber/catalyst composites for environment and energy applications
T. Kitaoka
Cellulose Communications, 10(4), 170-174 (2003)
The Cellulose Society of Japan. |
| 41. |
Preparation and environmental applications of paperlike photocatalyst composites
H. Tanaka, H. Ichiura, S. Fukahori, Y. Iguchi, T. Kitaoka
Annals of the High Performance Paper Society, Japan, 41, 7-15 (2003). |
| 42. |
A new conception in the design of papermaking additives based on the substrate recognition of cellulose-degrading enzymes
T. Kitaoka
Cellulose Communications, 8(4), 177-180 (2001)
The Cellulose Society of Japan. |
| 43. |
Molecular design of water-soluble polymer in paper chemistry
H. Tanaka, T. Kitaoka
Sen'i Gakkaishi, 56(5), P141-P145 (2000)
The Society of Fiber Science and Technology, Japan. |
