Articles citing this paper
Supramolecular Polymers Based on Cyclodextrins and Their Derivatives
Akira Harada A B C and Akihito Hashidzume A
+ Author Affiliations
- Author Affiliations
A Department of Macromolecular Science, Graduate School of Science, Osaka University, 1-1 Machikaneyama-cho, Toyonaka, Osaka 560-0043, Japan.
B Core Research for Evolutional Science and Technology (CREST), Japan Science and Technology Agency (JST), 5 Sanban-cho, Chiyoda-ku, Tokyo 102-0075, Japan.
C Corresponding author. Email: harada@chem.sci.osaka-u.ac.jp
Professor Akira Harada is a Professor at the Graduate School of Science at Osaka University. He earned his academic degrees from Osaka University and has spent most of his career working for the same university. During his career, Dr Harada worked for IBM Research as a visiting scientist and as a postdoc at Colorado State University. After working at the Institute of Scientific and Industrial Research (ISIR) at Osaka University, he assumed his current position as a professor. Harada’s work and research interests include supramolecular science, synthetic polymer chemistry, and biomacromolecules (e.g. antibodies and DNA). He has received many awards, including the IBM Science Award, Osaka Science Award, Japan Polymer Society Award, Cyclodextrin Society Award, a Medal with Purple Ribbon from the Japanese Government, and the International Izatt-Christensen Award in Macrocyclic Chemistry.
|
Akihito Hashidzume is an Associate Professor at the Graduate School of Science, Osaka University. He completed his Doctorate of Science from Osaka University in 1997 under the supervision of Professor Mikiharu Kamachi. After receiving his Ph.D., he began working at the Graduate School of Science, Osaka University, as an Assistant Professor. During his academic career, he worked as a visiting scholar with Professor Steven C. Zimmerman at the University of Illinois at Urbana-Champaign. He received the Society of Cyclodextrins Japan Award for Young Scientists in 2008. His research interests include polymer synthesis, water-soluble polymers, and polymer assemblies.
|
Australian Journal of Chemistry 63(4) 599-610 https://doi.org/10.1071/CH09609
Submitted: 25 November 2009 Accepted: 1 February 2010 Published: 8 April 2010
Supramolecular self-healing materials via host-guest strategy between cyclodextrin and specific types of guest molecules
Mohamadhoseini Masoumeh, Mohamadnia Zahra
Coordination Chemistry Reviews. 2021 432 p.213711
Shell Cross‐linking of Cyclodextrin‐Based Micelles via Supramolecular Chemistry for the Delivery of Drugs
Yhaya Firdaus,
Binauld Sandra,
Kim Yoseop, Stenzel Martina H.
Macromolecular Rapid Communications. 2012 33(21). p.1868
Complex Formation of Cyclodextrins with a Dumbbell Molecule Bearing Two Ferrocene Moieties at the Ends
Yamamoto Takaya,
Oi Wataru,
Hashidzume Akihito, Harada Akira
Bulletin of the Chemical Society of Japan. 2011 84(9). p.918
Precisely Designed Difunctionalized Cyclodextrin Produces a Solid‐State Organic Porous Hierarchical Supramolecular Assembly
Colesnic Dmitri,
Hernando Pedro J.,
Chamoreau Lise‐Marie,
Bouteiller Laurent,
Ménand Mickaël, Sollogoub Matthieu
Chemistry – A European Journal. 2023 29(35).
Supramolecular host–guest polymeric materials for biomedical applications
Loh Xian Jun
Mater. Horiz.. 2014 1(2). p.185
Cyclodextrin-functionalized graphene nanosheets, and their host-guest polymer nanohybrids
Xu Li Qun,
Yee Yon Kiat,
Neoh Koon-Gee,
Kang En-Tang, Fu Guo Dong
Polymer. 2013 54(9). p.2264
A novel supramolecular ternary polymer with two orthogonal host–guest interactions
Zhao Hong-Xia,
Guo Dong-Sheng,
Wang Li-Hua,
Qian Hai, Liu Yu
Chemical Communications. 2012 48(92). p.11319
Functional Polymers by Post‐Polymerization Modification (2012)
Sakai Ryosuke, Kakuchi Toyoji
Photocatalytic H2 production in aqueous solution with host-guest inclusions formed by insertion of an FeFe-hydrogenase mimic and an organic dye into cyclodextrins
Li Xueqiang,
Wang Mei,
Zheng Dehua,
Han Kai,
Dong Jingfeng, Sun Licheng
Energy & Environmental Science. 2012 5(8). p.8220
Theoretical study on the formation process of Cross-Linked β-Cyclodextrin molecular tubes
Reis Vitória S.,
Santos Eliziane S.,
Bonsolhos Daniela N.F.,
Guimarães Luciana,
De Almeida Wagner B., Nascimento Clebio S.
Chemical Physics Letters. 2017 677 p.13
Materials Science and Technology (2012)
Harada Akira, Yamaguchi Hiroyasu
Encyclopedia of Polymer Science and Technology (2012)
Harada Akira,
Hashidzume Akihito,
Yamaguchi Hiroyasu, Takashima Yoshinori
Synthesis and Characterization of PNIPAm Core Cross‐Linked Star Polymers and Their Functionalization with Cyclodextrin
Liu Yu‐Yang,
Lan Song, Xiao Li‐Qun
Macromolecular Chemistry and Physics. 2015 216(7). p.749
Comprehensive Supramolecular Chemistry II (2017)
Hashidzume A.,
Takashima Y.,
Yamaguchi H., Harada A.
Solid‐State Hierarchical Cyclodextrin‐Based Supramolecular Polymer Constructed by Primary, Secondary, and Tertiary Azido Interactions
Ménand Mickaël,
Adam de Beaumais Ségolène,
Chamoreau Lise‐Marie,
Derat Etienne,
Blanchard Sébastien,
Zhang Yongmin,
Bouteiller Laurent, Sollogoub Matthieu
Angewandte Chemie. 2014 126(28). p.7366
Photoregulated Switching of the Recognition Site of α‐Cyclodextrin in a Side Chain Polyrotaxane Bearing Two Recognition Sites Linked with Oligo(ethylene glycol)
Hu Jie,
Hashidzume Akihito, Harada Akira
Macromolecular Chemistry and Physics. 2011 212(10). p.1032
Self‐Healing of Electrical Damage in Polymers
Yang Yang,
Dang Zhi‐Min,
Li Qi, He Jinliang
Advanced Science. 2020 7(21).
Hydroxypropyl-β-CD vs. its α-homologue for a 3D modified polyrotaxane network formation and properties: the relationship between modified CD and polymer revealed through comparison
Li Zhao,
Zheng Zhen,
Su Shan,
Yu Lin, Wang Xinling
Soft Matter. 2016 12(34). p.7089
Solid‐State Hierarchical Cyclodextrin‐Based Supramolecular Polymer Constructed by Primary, Secondary, and Tertiary Azido Interactions
Ménand Mickaël,
Adam de Beaumais Ségolène,
Chamoreau Lise‐Marie,
Derat Etienne,
Blanchard Sébastien,
Zhang Yongmin,
Bouteiller Laurent, Sollogoub Matthieu
Angewandte Chemie International Edition. 2014 53(28). p.7238
Macromolecular recognition: Recognition of polymer side chains by cyclodextrin
(2015)
Hashidzume Akihito, Harada Akira
Cyclodextrin‐Based Rotaxanes: from Rotaxanes to Polyrotaxanes and Further to Functional Materials
Hashidzume Akihito,
Yamaguchi Hiroyasu, Harada Akira
European Journal of Organic Chemistry. 2019 2019(21). p.3344
One-Pot Endgroup-Modification of Hydrophobic RAFT Polymers with Cyclodextrin by Thiol-ene Chemistry and the Subsequent Formation of Dynamic Core–Shell Nanoparticles Using Supramolecular Host–Guest Chemistry
Yhaya Firdaus,
Binauld Sandra,
Callari Manuela, Stenzel Martina H.
Australian Journal of Chemistry. 2012 65(8). p.1095
Supramolecular Polymer Chemistry (2011)
Hashidzume Akihito, Harada Akira
Recognition of polymer side chains by cyclodextrins
Hashidzume Akihito, Harada Akira
Polymer Chemistry. 2011 2(10). p.2146
Supramolecular Four-Armed Star A2B2 Copolymer (Miktoarm Star) via Host–Guest Complexation and Nitroxide-Mediated Radical Polymerization
Lee Minjae, Gibson Harry W.
Macromolecules. 2020 53(13). p.5399
Thermomechanical behavior of hydrogen-bond based supramolecular poly(ε-caprolactone)-silica nanocomposites
Neikirk Colin C.,
Chung Jae Woo, Priestley Rodney D.
RSC Advances. 2013 3(37). p.16686
Interaction of cyclodextrins with pyrene-modified polyacrylamide in a mixed solvent of water and dimethyl sulfoxide as studied by steady-state fluorescence
Hashidzume Akihito,
Zheng Yongtai, Harada Akira
Beilstein Journal of Organic Chemistry. 2012 8 p.1312
