Angewandte Chemie International Edition

Number of times cited: 71

• Yuezhou Zhang, Jing Tu, Dongqing Wang, Haitao Zhu, Sajal Kumar Maity, Xiangmeng Qu, Bram Bogaert, Hao Pei and Hongbo Zhang, Programmable and Multifunctional DNA‐Based Materials for Biomedical Applications, Advanced Materials, 30, 24, (2018).
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• William P. Klein, Sebastián A. Díaz, Susan Buckhout‐White, Joseph S. Melinger, Paul D. Cunningham, Ellen R. Goldman, Mario G. Ancona, Wan Kuang and Igor L. Medintz, Utilizing HomoFRET to Extend DNA‐Scaffolded Photonic Networks and Increase Light‐Harvesting Capability, Advanced Optical Materials, 6, 1, (2017).
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• Larry J. Kricka, Paolo Fortina and Jason Y. Park, Nanostructured luminescently labeled nucleic acids, Luminescence, 32, 2, (132-141), (2016).
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• Aymen Skhiri, Ridha Ben Salem, Jean‐François Soulé and Henri Doucet, Unprecedented Access to β‐Arylated Selenophenes through Palladium‐Catalysed Direct Arylation, Chemistry – A European Journal, 23, 12, (2788-2791), (2017).
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• Sarah Helmig and Kurt Vesterager Gothelf, AFM Imaging of Hybridization Chain Reaction Mediated Signal Transmission between Two DNA Origami Structures, Angewandte Chemie, 129, 44, (13821-13824), (2017).
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• Fan Hong, Fei Zhang, Yan Liu and Hao Yan, DNA Origami: Scaffolds for Creating Higher Order Structures, Chemical Reviews, 10.1021/acs.chemrev.6b00825, 117, 20, (12584-12640), (2017).
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• Divita Mathur and Igor L. Medintz, Analyzing DNA Nanotechnology: A Call to Arms For The Analytical Chemistry Community, Analytical Chemistry, 10.1021/acs.analchem.6b04033, 89, 5, (2646-2663), (2017).
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• Madhabi M. Bhanjadeo, Ashok K. Nayak and Umakanta Subudhi, Surface-assisted DNA self-assembly: An enzyme-free strategy towards formation of branched DNA lattice, Biochemical and Biophysical Research Communications, 485, 2, (492), (2017).
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• Chao Chen, Ross A. L. Wylie, Daniel Klinger and Luke A. Connal, Shape Control of Soft Nanoparticles and Their Assemblies, Chemistry of Materials, 10.1021/acs.chemmater.6b04700, 29, 5, (1918-1945), (2017).
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• Sarah Helmig and Kurt Vesterager Gothelf, AFM Imaging of Hybridization Chain Reaction Mediated Signal Transmission between Two DNA Origami Structures, Angewandte Chemie International Edition, 56, 44, (13633-13636), (2017).
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• Wolfgang Pfeifer and Barbara Saccà, From Nano to Macro through Hierarchical Self‐Assembly: The DNA Paradigm, ChemBioChem, 17, 12, (1063-1080), (2016).
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• Tieqiao Chen, Ji-Shu Zhang and Li-Biao Han, Dehydrogenative coupling involving P(O)–H bonds: a powerful way for the preparation of phosphoryl compounds, Dalton Transactions, 45, 5, (1843), (2016).
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• Saminathan Ramakrishnan, Sivaraman Subramaniam, A. Francis Stewart, Guido Grundmeier and Adrian Keller, Regular Nanoscale Protein Patterns via Directed Adsorption through Self-Assembled DNA Origami Masks, ACS Applied Materials & Interfaces, 8, 45, (31239), (2016).
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• Risheng Wang, Kent Gorday, Colin Nuckolls and Shalom J. Wind, Control of DNA origami inter-tile connection with vertical linkers, Chemical Communications, 52, 8, (1610), (2016).
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• Hesheng Victor Xu, Xin Ting Zheng, Beverly Yin Leng Mok, Salwa Ali Ibrahim, Yong Yu and Yen Nee Tan, Molecular Design of Bioinspired Nanostructures for Biomedical Applications: Synthesis, Self-Assembly and Functional Properties, Journal of Molecular and Engineering Materials, 10.1142/S2251237316400037, 04, 01, (1640003), (2016).
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• Weina Fang, Jianbang Wang and Huajie Liu, Smart Materials for DNA-Based Nanoconstructions, Design, Fabrication, Properties and Applications of Smart and Advanced Materials, 10.1201/b19977-3, (13-52), (2016).
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• Guangbao Yao, Jiang Li, Jie Chao, Hao Pei, Huajie Liu, Yun Zhao, Jiye Shi, Qing Huang, Lianhui Wang, Wei Huang and Chunhai Fan, Gold‐Nanoparticle‐Mediated Jigsaw‐Puzzle‐like Assembly of Supersized Plasmonic DNA Origami, Angewandte Chemie International Edition, 54, 10, (2966-2969), (2015).
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• Guangbao Yao, Jiang Li, Jie Chao, Hao Pei, Huajie Liu, Yun Zhao, Jiye Shi, Qing Huang, Lianhui Wang, Wei Huang and Chunhai Fan, Gold‐Nanoparticle‐Mediated Jigsaw‐Puzzle‐like Assembly of Supersized Plasmonic DNA Origami, Angewandte Chemie, 127, 10, (3009-3012), (2015).
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• Miran Liber, Toma E. Tomov, Roman Tsukanov, Yaron Berger and Eyal Nir, A Bipedal DNA Motor that Travels Back and Forth between Two DNA Origami Tiles, Small, 11, 5, (568-575), (2014).
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• Shu Xing, Dawei Jiang, Fan Li, Jiang Li, Qian Li, Qing Huang, Linjie Guo, Jiaoyun Xia, Jiye Shi, Chunhai Fan, Lan Zhang and Lihua Wang, Constructing Higher-Order DNA Nanoarchitectures with Highly Purified DNA Nanocages, ACS Applied Materials & Interfaces, 10.1021/am505592e, 7, 24, (13174-13179), (2014).
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• Gang Chen, Di Liu, Chunbai He, Theodore R. Gannett, Wenbin Lin and Yossi Weizmann, Enzymatic Synthesis of Periodic DNA Nanoribbons for Intracellular pH Sensing and Gene Silencing, Journal of the American Chemical Society, 137, 11, (3844), (2015).
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• Govindan Prakash, Muthukumaran Nirmala, Rangasamy Ramachandran, Periasamy Viswanathamurthi, Jan Grzegorz Malecki and Jesus Sanmartin, Heteroleptic binuclear copper(I) complexes bearing bis(salicylidene)hydrazone ligands: Synthesis, crystal structure and application in catalytic N-alkylation of amines, Polyhedron, 10.1016/j.poly.2014.12.015, 89, (62-69), (2015).
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• Philipp C. Nickels, Yonggang Ke, Ralf Jungmann, David M. Smith, Marc Leichsenring, William M. Shih, Tim Liedl and Björn Högberg, DNA Origami Structures Directly Assembled from Intact Bacteriophages, Small, 10, 9, (1765-1769), (2014).
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• Maria Tintoré, Ramon Eritja and Carmen Fábrega, DNA Nanoarchitectures: Steps towards Biological Applications, ChemBioChem, 15, 10, (1374-1390), (2014).
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• Cheng Tian, Xiang Li, Zhiyu Liu, Wen Jiang, Guansong Wang and Chengde Mao, Directed Self‐Assembly of DNA Tiles into Complex Nanocages, Angewandte Chemie, 126, 31, (8179-8182), (2014).
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• Silvia Hernández-Ainsa and Ulrich F. Keyser, DNA origami nanopores: developments, challenges and perspectives, Nanoscale, 6, 23, (14121), (2014).
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• Alexandria N. Marchi, Ishtiaq Saaem, Briana N. Vogen, Stanley Brown and Thomas H. LaBean, Toward Larger DNA Origami, Nano Letters, 14, 10, (5740), (2014).
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• Elisabeth P. Gates, Andrew M. Dearden and Adam T. Woolley, DNA‐templated lithography and nanofabrication for the fabrication of nanoscale electronic circuitry, Critical Reviews in Analytical Chemistry, 10.1080/10408347.2014.910636, 44, 4, (354-370), (2014).
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• Cheng Tian, Xiang Li, Zhiyu Liu, Wen Jiang, Guansong Wang and Chengde Mao, Directed Self‐Assembly of DNA Tiles into Complex Nanocages, Angewandte Chemie International Edition, 53, 31, (8041-8044), (2014).
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• Chen Song, Zhen‐Gang Wang and Baoquan Ding, Smart Nanomachines Based on DNA Self‐Assembly, Small, 9, 14, (2382-2392), (2013).
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• Karina M. M. Carneiro, Nicole Avakyan and Hanadi F. Sleiman, Long‐range assembly of DNA into nanofibers and highly ordered networks, Wiley Interdisciplinary Reviews: Nanomedicine and Nanobiotechnology, 5, 3, (266-285), (2013).
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• Ishtiaq Saaem and Thomas H. LaBean, Overview of DNA origami for molecular self‐assembly, Wiley Interdisciplinary Reviews: Nanomedicine and Nanobiotechnology, 5, 2, (150-162), (2013).
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• Junwye Lee, Shogo Hamada, Si Un Hwang, Rashid Amin, Junyoung Son, Sreekantha Reddy Dugasani, Satoshi Murata and Sung Ha Park, Quantitative analysis of molecular-level DNA crystal growth on a 2D surface, Scientific Reports, 3, 1, (2013).
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• Zhao Zhang, Jie Song, Flemming Besenbacher, Mingdong Dong and Kurt V. Gothelf, Self‐Assembly of DNA Origami and Single‐Stranded Tile Structures at Room Temperature, Angewandte Chemie, 125, 35, (9389-9393), (2013).
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• Haorong Chen, Tae-Gon Cha, Jing Pan and Jong Hyun Choi, Hierarchically assembled DNA origami tubules with reconfigurable chirality, Nanotechnology, 10.1088/0957-4484/24/43/435601, 24, 43, (435601), (2013).
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• Yun-He Xu, Min Wang, Ping Lu and Teck-Peng Loh, Palladium-catalyzed alkenyl C–H bond sulfonylation reaction using organosulfonyl chlorides, Tetrahedron, 69, 22, (4403), (2013).
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• Hassan Said, Verena J. Schüller, Fabian J. Eber, Christina Wege, Tim Liedl and Clemens Richert, M1.3 – a small scaffold for DNA origami , Nanoscale, 5, 1, (284), (2013).
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• Yanming Fu, Dongdong Zeng, Jie Chao, Yanqiu Jin, Zhao Zhang, Huajie Liu, Di Li, Hongwei Ma, Qing Huang, Kurt V. Gothelf and Chunhai Fan, Single-Step Rapid Assembly of DNA Origami Nanostructures for Addressable Nanoscale Bioreactors, Journal of the American Chemical Society, 135, 2, (696), (2013).
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• Zhao Zhang, Jie Song, Flemming Besenbacher, Mingdong Dong and Kurt V. Gothelf, Self‐Assembly of DNA Origami and Single‐Stranded Tile Structures at Room Temperature, Angewandte Chemie International Edition, 52, 35, (9219-9223), (2013).
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• Divita Mathur and Eric R. Henderson, Complex DNA Nanostructures from Oligonucleotide Ensembles, ACS Synthetic Biology, 2, 4, (180), (2013).
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• Arivazhagan Rajendran, Masayuki Endo, Kumi Hidaka and Hiroshi Sugiyama, Control of the two-dimensional crystallization of DNA origami with various loop arrangements, Chem. Commun., 49, 7, (686), (2013).
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• Zhen-Gang Wang and Baoquan Ding, DNA Nanotechnology as Reference for RNA Nanotechnology, RNA Nanotechnology and Therapeutics, 10.1201/b15152-23, (313-360), (2013).
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• Eugen Czeizler and Alexandru Popa, Synthesizing minimal tile sets for complex patterns in the framework of patterned DNA self-assembly, Theoretical Computer Science, 499, (23), (2013).
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• Niancao Chen, Shihui Li, Mark R. Battig and Yong Wang, Programmable Imaging Amplification via Nanoparticle‐Initiated DNA Polymerization, Small, 9, 23, (3944-3949), (2013).
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• YanMing Fu, Jie Chao, HuaJie Liu and ChunHai Fan, Programmed self-assembly of DNA origami nanoblocks into anisotropic higher-order nanopatterns, Chinese Science Bulletin, 58, 21, (2646), (2013).
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• Masayuki Endo, Yangyang Yang and Hiroshi Sugiyama, DNA origami technology for biomaterials applications, Biomater. Sci., 1, 4, (347), (2013).
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• Barbara Saccà and Christof M. Niemeyer, DNA Origami: The Art of Folding DNA, Angewandte Chemie International Edition, 51, 1, (58-66), (2011).
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• Shiheng Liao, Kangkang Yu, Qiang Li, Haiwen Tian, Zhengping Zhang, Xiaochun Yu and Qing Xu, Copper-catalyzed C-alkylation of secondary alcohols and methyl ketones with alcohols employing the aerobic relay race methodology, Organic & Biomolecular Chemistry, 10.1039/c1ob06739g, 10, 15, (2973), (2012).
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• Arivazhagan Rajendran, Masayuki Endo and Hiroshi Sugiyama, Einzelmolekülanalysen mithilfe von DNA‐Origami, Angewandte Chemie, 124, 4, (898-915), (2011).
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• Karina M. M. Carneiro, Pik Kwan Lo and Hanadi F. Sleiman, Self‐Assembly of Nucleic Acids, Supramolecular Chemistry, (2012).
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• Arivazhagan Rajendran, Masayuki Endo and Hiroshi Sugiyama, DNA Origami: Synthesis and Self‐Assembly, Current Protocols in Nucleic Acid Chemistry, 48, 1, (12.9.1-12.9.18), (2012).
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• Zhe Li, Lei Wang, Hao Yan and Yan Liu, Effect of DNA Hairpin Loops on the Twist of Planar DNA Origami Tiles, Langmuir, 10.1021/la2037873, 28, 4, (1959-1965), (2011).
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• Arivazhagan Rajendran, Masayuki Endo and Hiroshi Sugiyama, Single‐Molecule Analysis Using DNA Origami, Angewandte Chemie International Edition, 51, 4, (874-890), (2011).
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• Qiang Li, Songjian Fan, Qing Sun, Haiwen Tian, Xiaochun Yu and Qing Xu, Copper-catalyzed N-alkylation of amides and amines with alcohols employing the aerobic relay race methodology, Organic & Biomolecular Chemistry, 10.1039/c1ob06743e, 10, 15, (2966), (2012).
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• Yoshiaki Hirano, Kaoru Ojima, Yusuke Miyake, Tomoji Kawai and Takuya Matsumoto, Emergence of High-density DNA Origami Network by Dewetting with a Binary Solvent, Chemistry Letters, 41, 11, (1459), (2012).
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• Barbara Saccà and Christof M. Niemeyer, DNA‐Origami: die Kunst, DNA zu falten, Angewandte Chemie, 124, 1, (60-69), (2011).
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• Marya Lieberman, DNA Nanostructures, The Nanobiotechnology Handbook, 10.1201/b12935-3, (3-30), (2013).
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• Honglu Zhang, Jie Chao, Dun Pan, Huajie Liu, Qing Huang and Chunhai Fan, Folding super-sized DNA origami with scaffold strands from long-range PCR, Chemical Communications, 48, 51, (6405), (2012).
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• Kyoung Nan Kim, Koshala Sarveswaran, Lesli Mark and Marya Lieberman, Comparison of methods for orienting and aligning DNA origami, Soft Matter, 7, 10, (4636), (2011).
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• H. Li, T. H. LaBean and K. W. Leong, Nucleic acid-based nanoengineering: novel structures for biomedical applications, Interface Focus, 10.1098/rsfs.2011.0040, 1, 5, (702-724), (2011).
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• Masayuki Endo, Tsutomu Sugita, Arivazhagan Rajendran, Yousuke Katsuda, Tomoko Emura, Kumi Hidaka and Hiroshi Sugiyama, Two-dimensional DNA origami assemblies using a four-way connector, Chemical Communications, 47, 11, (3213), (2011).
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• Masayuki Endo, Yangyang Yang, Tomoko Emura, Kumi Hidaka and Hiroshi Sugiyama, Programmed placement of gold nanoparticles onto a slit-type DNA origami scaffold, Chemical Communications, 47, 38, (10743), (2011).
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• Thomas Tørring, Niels V. Voigt, Jeanette Nangreave, Hao Yan and Kurt V. Gothelf, DNA origami: a quantum leap for self-assembly of complex structures, Chemical Society Reviews, 40, 12, (5636), (2011).
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• Yuanqin Zheng and Zhaoxiang Deng, Nanostructures and Nanomaterials via DNA-Based Self-Assembly, Materials Science of DNA, 10.1201/b11290-3, (13-48), (2011).
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• Masayuki Endo and Hiroshi Sugiyama, DNA Origami-based Construction of Meso-scale Multi-dimensional Architects and Expression of the Functionality in the Designed DNA Nanospace, Journal of Synthetic Organic Chemistry, Japan, 69, 12, (1352), (2011).
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• Enjun Cheng, Yulin Li, Zhongqiang Yang, Zhaoxiang Deng and Dongsheng Liu, DNA-SWNT hybrid hydrogel, Chemical Communications, 10.1039/c1cc11028d, 47, 19, (5545), (2011).
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• Masayuki Endo and Hiroshi Sugiyama, Recent Progress in DNA Origami Technology, Current Protocols in Nucleic Acid Chemistry, 45, 1, (12.8.1-12.8.19), (2011).
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• Jeanette Nangreave, Dongran Han, Yan Liu and Hao Yan, DNA origami: a history and current perspective, Current Opinion in Chemical Biology, 10.1016/j.cbpa.2010.06.182, 14, 5, (608-615), (2010).
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• Dayong Yang, Michael J. Campolongo, Thua Nguyen Nhi Tran, Roanna C. H. Ruiz, Jason S. Kahn and Dan Luo, Novel DNA materials and their applications, Wiley Interdisciplinary Reviews: Nanomedicine and Nanobiotechnology, 2, 6, (648-669), (2010).
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• Andre V. Pinheiro, Dongran Han, William M. Shih and Hao Yan, Challenges and opportunities for structural DNA nanotechnology, Nature Nanotechnology, 10.1038/nnano.2011.187, 6, 12, (763-772), (2011)., (2011).
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• Ying Liu, Sriram Kumar and Rebecca E. Taylor, Mix‐and‐match nanobiosensor design: Logical and spatial programming of biosensors using self‐assembled DNA nanostructures, Wiley Interdisciplinary Reviews: Nanomedicine and Nanobiotechnology, e1518, (2018).
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