{"id":3510,"date":"2021-10-04T06:05:09","date_gmt":"2021-10-03T21:05:09","guid":{"rendered":"https:\/\/wps.itc.kansai-u.ac.jp\/mol-mach\/?page_id=3510"},"modified":"2024-09-02T15:06:22","modified_gmt":"2024-09-02T06:06:22","slug":"qing_liu","status":"publish","type":"page","link":"https:\/\/wps.itc.kansai-u.ac.jp\/mol-mach\/members\/qing_liu\/","title":{"rendered":"\u5289 \u6e05\uff08\u308a\u3085\u3046 \u305b\u3044\uff09"},"content":{"rendered":"\n

\u5148\u7aef\u79d1\u5b66\u6280\u8853\u63a8\u9032\u6a5f\u69cb \u30dd\u30b9\u30c8\u30c9\u30af\u30c8\u30e9\u30eb\uff65\u30d5\u30a7\u30ed\u30fc\uff08NEDO AI\u5171\u5275\u5206\u5b50\u30ed\u30dc\u30c3\u30c8\u958b\u767a<\/a>\uff09<\/p>\n\n\n\n

ID: r218174 \u2003 \u5185\u7dda: 6044<\/p>\n\n\n\n

\u7565\u6b74<\/h4>\n\n\n\n
2009\u5e747\u6708<\/td>\u4e2d\u56fd \u5317\u4eac\u5316\u5de5\u5927\u5b66\u7406\u5b66\u90e8 \u5352\u696d<\/td><\/tr>
2014\u5e747\u6708<\/td>\u4e2d\u56fd \u4e2d\u56fd\u79d1\u5b66\u9662\u5927\u5b66\u56fd\u5bb6\u30ca\u30ce\u30e1\u30fc\u30c8\u30eb\u79d1\u5b66\u30bb\u30f3\u30bf\u30fc\u751f\u7269\u5de5\u5b66\u5c02\u653b \u4fee\u58eb\u8ab2\u7a0b \u4fee\u4e86<\/td><\/tr>
2018\u5e741\u6708<\/td>\u4e2d\u56fd \u4e2d\u56fd\u79d1\u5b66\u9662\u5927\u5b66\u56fd\u5bb6\u30ca\u30ce\u30e1\u30fc\u30c8\u30eb\u79d1\u5b66\u30bb\u30f3\u30bf\u30fc\u7269\u7406\u5316\u5b66\u5c02\u653b \u535a\u58eb\u8ab2\u7a0b \u4fee\u4e86<\/td><\/tr>
<\/td>\u7406\u5b66\u535a\u58eb \u53d6\u5f97<\/td><\/tr>
2018\u5e741\u6708<\/td>\u4e2d\u56fd \u56fd\u5bb6\u30ca\u30ce\u30e1\u30fc\u30c8\u30eb\u79d1\u5b66\u30bb\u30f3\u30bf\u30fc  \u7814\u7a76\u52a9\u624b<\/td><\/tr>
2021\u5e747\u6708<\/td>\u95a2\u897f\u5927\u5b66\u5148\u7aef\u79d1\u5b66\u6280\u8853\u63a8\u9032\u6a5f\u69cb \u30dd\u30b9\u30c8\u30c9\u30af\u30c8\u30e9\u30eb\uff65\u30d5\u30a7\u30ed\u30fc<\/td><\/tr>
2022\u5e748\u6708<\/td>\u65e5\u672c\u5b66\u8853\u632f\u8208\u4f1a \u5916\u56fd\u4eba\u7279\u5225\u7814\u7a76\u54e1\uff08\u95a2\u897f\u5927\u5b66\u5316\u5b66\u751f\u547d\u5de5\u5b66\u90e8\uff09<\/td><\/tr>
\u00a02024\u5e749\u6708<\/td>\u95a2\u897f\u5927\u5b66\u5148\u7aef\u79d1\u5b66\u6280\u8853\u63a8\u9032\u6a5f\u69cb \u30dd\u30b9\u30c8\u30c9\u30af\u30c8\u30e9\u30eb\uff65\u30d5\u30a7\u30ed\u30fc<\/td><\/tr>
<\/td>\u73fe\u5728\u306b\u81f3\u308b<\/td><\/tr><\/tbody><\/table><\/figure>\n\n\n\n

\u5b66\u8853\u8ad6\u6587<\/h4>\n\n\n\n
Genetically Encoded DNA Origami for Gene Therapy In Vivo<\/a><\/td><\/tr>
X Wu, C Yang, H Wang, X Lu, Y Shang, Q Liu<\/strong>, J Fan, J Liu*, B Ding*<\/td><\/tr>
J. Am. Chem. Soc.<\/em>, 2023<\/strong>, 145<\/em>, 9343\u20139353.<\/td><\/tr>
Supramolecular enzyme-mimicking catalysts self-assembled from peptides<\/a><\/td><\/tr>
Q Liu<\/strong>*, A Kuzuya, Z Wang*<\/td><\/tr>
iScience<\/em>, 2023<\/strong>, 26<\/em>, 105831.<\/td><\/tr>
A DNA-Based Plasmonic Nanodevice for Cascade Signal Amplification<\/a><\/td><\/tr>
F Liu, N Li, Y Shang, Y Wang, Q Liu<\/strong>, Z Ma, Q Jiang*, B Ding*<\/td><\/tr>
Angew. Chem. Int. Ed.<\/em>, 2022<\/strong>, 61<\/em>, e202114706.<\/td><\/tr>
Genetically Encoded Double-Stranded DNA-Based Nanostructure Folded by a Covalently Bivalent CRISPR\/dCas System<\/a><\/td><\/tr>
T Wu, Y Cao, Q Liu<\/strong>, X Wu, Y Shang, J Piao, Y Li, Y Dong, D Liu, H Wang*, J Liu*, B Ding*<\/td><\/tr>
J. Am. Chem. Soc.<\/em>, 2022<\/strong>, 144<\/em>, 6575\u20136582.<\/td><\/tr>
Cofactor-free oxidase-mimetic nanomaterials from self-assembled histidine-rich peptides<\/a><\/td><\/tr>
Q Liu<\/strong>+<\/sup>, K Wan+<\/sup>, Y Shang, Z Wang*, Y Zhang, L Dai, C Wang, H Wang*, X Shi, D Liu, B Ding*<\/td><\/tr>
Nature Mater<\/em>., 2021,<\/strong> 20<\/em>, 395\u2013402.<\/td><\/tr>
A DNA origami-based aptamer nanoarray for potent and reversible anticoagulation in hemodialysis<\/a><\/td><\/tr>
S Zhao, R Tian, J Wu, S Liu, Y Wang, M Wen, Y Shang, Q Liu<\/strong>, Y Li, Y Guo, Z Wang, T Wang, Y Zhao, H Zhao, H Cao, Y Su, J Sun, Q Jiang*, B Ding*<\/td><\/tr>
Nature Commun.<\/em>, 2021<\/strong>, 12<\/em>, 358.<\/td><\/tr>
A tubular DNA nanodevice as a siRNA\/chemo-drug co-delivery vehicle for combined cancer therapy<\/a><\/td><\/tr>
Z Wang+<\/sup>, L Song+<\/sup>, Q Liu<\/strong>+<\/sup>, R Tian, Y Shang, F Liu, S Liu, S Zhao, Z Han, J Sun, Q Jiang*, B Ding*<\/td><\/tr>
Angew. Chem. Int. Ed.<\/em>, 2021<\/strong>, 60<\/em>, 2594\u20132598.<\/td><\/tr>
An RNA\/DNA hybrid origami-based nanoplatform for efficient gene therapy<\/a><\/td><\/tr>
X Wu, Q Liu<\/strong>, F Liu, T Wu, Y Shang, J Liu*, B Ding*<\/td><\/tr>
Nanoscale<\/em>, 2021<\/strong>, 13, 30.<\/td><\/tr>
Logic gated plasmonic nanodevices based on DNA-templated assembly<\/a><\/td><\/tr>
F Liu, Q Jiang, Q Liu<\/strong>, N Li, Z Han, C Liu, Z Wang, Y Jiao, J Sun, B Ding*<\/td><\/tr>
CCS Chem.<\/em>, 2021<\/strong>, 3, 985\u2013993.<\/td><\/tr>
Multifunctional double bundle DNA tetrahedron for efficient regulation of gene expression<\/a><\/td><\/tr>
T Wu, Q Liu<\/strong>, Y Cao, R Tian, J Liu*, B Ding*<\/td><\/tr>
ACS Appl. Mater. Interfaces<\/em>, 2020<\/strong>, 12<\/em>, 32461\u201332467.<\/td><\/tr>
Rationally Designed DNA Assemblies for Biomedical Application<\/a><\/td><\/tr>
Q Jiang, Q Liu<\/strong>, Z Wang, B Ding*<\/td><\/tr>
Nanotechnology in Regenerative Medicine and Drug Delivery Therapy<\/em>, 2020<\/strong>, 287\u2013310.<\/td><\/tr>
Enzyme mimic basing on self-assembled chitosan\/DNA hybrid exhibits superior activity and tolerance<\/a><\/td><\/tr>
Z Wang, Y Li, H Wang, K Wan, Q Liu<\/strong>, X Shi, B Ding*<\/td><\/tr>
Chem. Eur. J.<\/em>, 2019<\/strong>, 25<\/em>, 12576\u201312582.<\/td><\/tr>
Designed self-assembly of peptides with G-quadruplex\/hemin DNAzyme into nanofibrils possessing enzyme-mimicking active sites and catalytic functions<\/a><\/td><\/tr>
Z Wang*+<\/sup>, H Wang+<\/sup>, Q Liu<\/strong>+<\/sup>, F Duan, X Shi*, B Ding*<\/td><\/tr>
ACS Catalysis<\/em>, 2018<\/strong>, 8<\/em>, 7016\u20137024.<\/td><\/tr>
Self-assembled double bundle DNA tetrahedron for efficient antisense delivery<\/a><\/em><\/td><\/tr>
J Yang, Q Jiang, L He, P Zhan, Q Liu<\/strong>, S Liu, M Fu, J Liu*, C Li*, B Ding*<\/td><\/tr>
ACS Appl. Mater. Interfac<\/em>es, 2018<\/strong>, 10<\/em>, 23693\u201323699.<\/td><\/tr>
A DNA-based nanocarrier for efficient gene delivery and combined cancer therapy<\/a><\/td><\/tr>
J Liu, L Song, S Liu, Q Jiang, Q Liu<\/strong>, N Li, Z Wang, B Ding*<\/td><\/tr>
Nano Lett<\/em>., 2018<\/strong>, 18<\/em>, 3328\u20133334.<\/td><\/tr>
Enhanced stability of DNA nanostructures by incorporation of unnatural base pairs<\/a><\/td><\/tr>
Q Liu<\/strong>+<\/sup>, G Liu+<\/sup>, T Wang+<\/sup>, J Fu, R Li, L Song, Z Wang*, B Ding*, F Chen*<\/td><\/tr>
ChemPhysChem<\/em>, 2017<\/strong>, 18<\/em>, 2977\u20132980.<\/td><\/tr>
Stimulus-responsive plasmonic chiral signals of gold nanorods organized on DNA origami<\/a><\/td><\/tr>
Q Jiang+<\/sup>, Q Liu<\/strong>+<\/sup>, Y Shi, Z Wang, P Zhan, J Liu, C Liu, H Wang, X Shi, L Zhang, J Sun*, B Ding*, M Liu*<\/td><\/tr>
Nano Lett.<\/em>, 2017<\/strong>, 17<\/em>, 7125\u20137130.<\/td><\/tr>
Self-assembled DNA\/peptide-based nanoparticle exhibiting synergistic enzymatic activity<\/a><\/td><\/tr>
Q Liu<\/strong>+<\/sup>, H Wang+<\/sup>, X Shi*, Z Wang*, B Ding*<\/td><\/tr>
ACS Nano<\/em>, 2017<\/strong>, 11,<\/em> 7251\u20137258.<\/td><\/tr>
DNA origami\/gold nanorod hybrid nanostructures for the circumvention of drug resistance<\/a><\/td><\/tr>
L Song, Q Jiang, J Liu, N Li, Q Liu<\/strong>, L Dai, Y Gao, W Liu, D Liu, B Ding*<\/td><\/tr>
Nanoscale<\/em>, 2017<\/strong>, 9<\/em>, 7750\u20137754.<\/td><\/tr>
Facilitation of DNA self-assembly by relieving the torsional strains between building blocks<\/a><\/td><\/tr>
W Shen, Q Liu<\/strong>, B Ding, C Zhu, Z Shen*, N C Seeman*<\/td><\/tr>
Org. Biomol. Chem.<\/em>, 2017<\/strong>, 15, 465\u2013469.<\/td><\/tr>
DNA-based nanotemplate directed in-situ synthesis of silver nanoclusters with specific fluorescent emission: surface-guided chemical reactions<\/a><\/td><\/tr>
Z Wang+<\/sup>, Q Liu<\/strong>+<\/sup>, N Li, B Ding*<\/td><\/tr>
Chem. Mater.<\/em>, 2016<\/strong>, 28<\/em>, 8834\u20138841.<\/td><\/tr>
The study of the paranemic crossover (PX) motif in the context of self-assembly of DNA 2D crystals<\/a><\/td><\/tr>
W Shen, Q Liu<\/strong>, B Ding, Z Shen*, C Zhu*, C Mao*<\/td><\/tr>
Org. Biomol. Chem.<\/em>, 2016<\/strong>, 14<\/em>, 7187\u20137190.<\/td><\/tr>
Precise organization of metal nanoparticles on DNA origami template<\/a><\/td><\/tr>
Q Liu<\/strong>, C Song, Z Wang, N Li, B Ding*<\/td><\/tr>
Methods<\/em>, 2014<\/strong>, 67<\/em>, 205\u2013214.<\/td><\/tr>
Shape-controlled nanofabrication of conducting polymer on planar DNA templates<\/a><\/td><\/tr>
Z Wang*, Q Liu<\/strong>, B Ding*<\/td><\/tr>
Chem. Mater.<\/em>, 2014<\/strong>, 26<\/em>, 3364\u20133367.<\/td><\/tr>
3D plasmonic chiral colloids<\/a><\/td><\/tr>
X Shen, P Zhan, A Kuzyk, Q Liu<\/strong>, A Asenjo-Garcia, H Zhang, F. J. G. Abajo, A Govorov, B Ding*, N Liu*<\/td><\/tr>
Nanoscale<\/em>, 2014<\/strong>, 6, 2077\u20132081.<\/td><\/tr>
DNA Origami as an In Vivo Drug Delivery Vehicle for Cancer Therapy<\/a><\/td><\/tr>
Q Zhang, Q Jiang, N Li, L Dai, Q Liu<\/strong>, L Song, J Wang, Y Li, J Tian, B Ding*, Y Du*<\/td><\/tr>
ACS Nano<\/em>, 2014<\/strong>, 8<\/em>, 6633\u20136643.<\/td><\/tr>
Three-dimensional plasmonic chiral tetramers assembled by DNA origami<\/a><\/td><\/tr>
X Shen, A Garcia, Q Liu<\/strong>, Q Jiang, J G Abajo, N Liu*, B Ding*<\/td><\/tr>
Nano Lett.<\/em>, 2013<\/strong>, 13<\/em>, 2128\u20132133.<\/td><\/tr>
Graphene-manganese oxide hybrid porous material and its application in carbon dioxide adsorption<\/a><\/td><\/tr>
D Zhou, Q Liu<\/strong>, Q Cheng, Y Zhao, Y Cui, T Wang, B Han*<\/td><\/tr>
Chinese Sci. Bull.<\/em>, 2012<\/strong>, 57<\/em>, 3059\u20133064.<\/td><\/tr>
Preparation of 5-fluorouracil\/\u03b2-cyclodextrin complex intercalated in layered double hydroxide and the controlled drug release properties<\/a><\/td><\/tr>
L Jin, Q Liu<\/strong>, Z Sun, X Ni, M Wei*<\/td><\/tr>
Ind. Eng. Chem. Res.<\/em>, 2010<\/strong>, 49<\/em>, 11176\u201311181.<\/td><\/tr><\/tbody><\/table><\/figure>\n","protected":false},"excerpt":{"rendered":"

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