Kyushu University Academic Staff Educational and Research Activities Database
List of Reports
Takuya Kitaoka Last modified date:2023.05.26

Professor / Sustainable Bioresources Science / Department of Agro-environmental Sciences / Faculty of Agriculture

1. Functional design of bioadaptive cell culture scaffolds regulated by structural polysaccharide nanofibers.
2. Takuya Kitaoka, Emerging Functions of Nano-Organized Polysaccharides, Nanomaterials, 10.3390/nano12081277, 12(8), 1277 (2022), 2022.04.
3. Creating new values of cellulose nanofibers.
4. Biofunction of cell culture scaffolds triggered by polysaccharide nanofibers.
5. Kojiro Uetani, Naliharifetra Jessica Ranaivoarimanana, Mayumi Hatakeyama, Takuya Kitaoka, Inherently Distinctive Potentialities and Uses of Nanocellulose Based on its Nanoarchitecture, BioResources, 2021.03.
6. Kojiro Uetani, Takuya Kitaoka, Nanocellulose: Beyond the Ordinary, BioResources, 16(1), 1-4 (2021), 2020.11.
7. Lignification-inspired Biomimetic Surface Modification of Wood Nanocellulose
N. Fukuda, K. Kanomata, T. Kitaoka.
8. Interfacial Design of Glyco-nanolayers for Cell Adhesion.
9. Knoevenagel condensation by chitosan nanofibers
Y. Hirayama, K. Kanomata, T. Kitaoka.
10. Interfacial Catalysis via Cellulose Nanofibers.
11. Interfacial Acid Hydrolysis of Acetals by Surface-carboxylated Nanocellulose
Y. Tamura, K. Kanomata, T. Kitaoka.
12. New Frontier of Paper-structured Catalysts.
13. Fischer-Tropsch Synthesis over Paper-Structured Catalysts
A. Saimura, T. Kitaoka.
14. Materials Design Inspired by Paper and Cellulose Architectures.
15. Structural and functional design of cellulose nanomaterials.
16. Microflow Chemical Synthesis over Stacked Paper-Structured Catalysts
Y. Ishihara, T. Kitaoka.
17. Cooperative catalysis by the combination of TEMPO-oxidized cellulose nanofibers and proline.
18. Emergent Functions of Nanocellulose Hybrid Materials
T. Kitaoka
19. Sequential Desulfurization and Methane Steam Reforming by Paper-Structured Catalysts
A. Saimura, Y. Shiratori, T. Kitaoka.
20. Cellulose Materials Innovation.
21. Blue Ocean Strategy in Wood Science and Industries.
22. Hirotaka Koga, Takuya Kitaoka, Akira Isogai, Chemically-modified cellulose paper as a microstructured catalytic reactor, Molecules, 20, 1495-1508 , 2015.01.
23. Selective Gas Separation by Hybrid Nanofilms of Cellulose and Metal-organic Frameworks
M. Matsumoto, T. Kitaoka.
24. Emerging Issues for Paper Materials
T. Kitaoka
Sen'i Gakkaishi, 70(9), P430-P433 (2014)
The Society of Fiber Science and Technology, Japan.
25. Introduction of Laboratory of Bioresources Chemistry, Kyushu University
T. Kitaoka
Kamipa Gikyoushi, 68(8), 80-81/914-915 (2014)
Japan TAPPI.
26. Functional Nano-Architectonics of Glyco-Biointerfaces
T. Kitaoka
Cellulose Communications, 20(2), 63-68 (2013)
The Cellulose Society of Japan.
27. Paper-like Catalysts for Environmental, Energy, Chemical and Biological Applications
Takuya Kitaoka
Journal of Packaging Science & Technology, Japan.
28. Structural and Functional Design of Cellulosic Nanohybrid Materials
T. Kitaoka
29. Koga H., Kitaoka T., On-paper synthesis of metal nanoparticles for catalytic applications, Sen'i Gakkaishi, 67(7), 141-152, 2011.07.
30. 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.
31. Development and Applications of Paper-Structured Catalysts
T. Kitaoka
32. Advanced Material Design and Applications of Cellulose
T. Kitaoka
Kobunshi, High Polymers.
33. Architectural Design and Functional Development of Cellulosic Nanolayers
T. Kitaoka, S. Yokota
Bioscience & Industry.
34. 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).
35. Development of Porous Catalyst/Fiber Composites by a Papermaking Technique
A. Tomoda, R. Suzuki, T. Kitaoka
Fuel Cell, 5(4), 83-87 (2006).
36. 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).
37. Catalyst Paper
T. Kitaoka
Sen'i Gakkaishi, 60(9), P439-P442 (2004)
The Society of Fiber Science and Technology, Japan.
38. Paperlike fiber/catalyst composites for environment and energy applications
T. Kitaoka
Cellulose Communications, 10(4), 170-174 (2003)
The Cellulose Society of Japan.
39. 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).
40. 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.
41. 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.