ReviewS

Biointerface engineering with nucleic acid materials for biosensing applications.

S Shi, J Chen, X Wang, M Xiao, AR Chandrasekaran, L Li, C Yi, H Pei
Advanced Functional Materials, 32: 2201069 (2022). [PDF]

Aptamers for viral detection and inhibition.

B Chakraborty,* S Das, A Gupta, Y Xiong, TV Vyshnavi , ME Kizer, J Duan, AR Chandrasekaran* & X Wang*
ACS Infectious Diseases, 8: 667 (2022). [PDF]

Aptamer-programmed DNA nanodevices for advanced, targeted cancer theranostics.

S Walia, AR Chandrasekaran, B Chakraborty & D Bhatia
ACS Applied Bio Materials, 4: 5392 (2021). [PDF]

Nuclease resistance of DNA nanostructures.

AR Chandrasekaran*
Nature Reviews Chemistry, 5: 225 (2021). [PDF]

DNA-based ribonuclease detection assays

AR Chandrasekaran*
J. Mater. Chem. B, 9: 7023 (2021). [PDF]

DNA-functionalized nanoparticles for targeted biosensing and biological applications.

U Singh, V Morya, A Rajwar, AR Chandrasekaran, B Datta, C Ghoroi & D Bhatia
ACS Omega 5: 30767 (2020). [PDF]

Designer, programmable 3D DNA nanodevices to probe biological systems.

A Rajwar, S Kharbanda, AR Chandrasekaran, S Gupta & D Bhatia
ACS Applied Bio Materials, 3: 7265 (2020). [PDF]

Processing DNA-based molecular signals into graphical displays.

AR Chandrasekaran*
ACS Synthetic Biology9: 1490 (2020). [PDF]

Rationally engineered nucleic acid architectures for biosensing applications.

M Xiao, W Lai, T Man, B Chang, L Li, AR Chandrasekaran* & H Pei*
Chemical Reviews, 119: 11631 (2019). [PDF]

DNA nanotechnology approaches for microRNA detection and diagnosis.

AR Chandrasekaran,* JA Punnoose, L Zhou, P Dey, BK Dey* & K Halvorsen*
Nucleic Acids Research, 47: 10489 (2019). [PDF]

A molecular hero suit for in vitro and in vivo DNA nanostructures.

ME Kizer, RJ Linhardt, AR Chandrasekaran* & X Wang*
Small, 15: 1805386 (2019). [PDF]

Nucleic acid nanotechnology.

AR Chandrasekaran*
Comprehensive Nanoscience and Nanotechnology, (Second Edition) 2: 13 (2019). [PDF]

DNA nanocarriers: Programmed to deliver.

BR Madhanagopal, S Zhang, E Demirel, H Wady & AR Chandrasekaran*
Trends in Biochemical Sciences, 43: 997 (2018). [PDF]

Paranemic crossover DNA: There and back again.

X Wang, AR Chandrasekaran,^* Z Shen, YP Ohayon, T Wang, ME Kizer, R Sha, C Mao, H Yan… & NC Seeman
Chemical Reviews, 119: 6273 (2018). [PDF]

DNA-based construction at the nanoscale: emerging trends and applications.

PL Xavier* & AR Chandrasekaran*
Nanotechnology, 29: 062001 (2018). [PDF]

Triplex-forming oligonucleotides: A third strand for DNA nanotechnology.

AR Chandrasekaran & DA Rusling
Nucleic Acids Research, 46: 1021 (2017). [PDF]

DNA nanocages.

AR Chandrasekaran* & O Levchenko
Chemistry of Materials, 28: 5569 (2016). [PDF]

Nucleic acid nanostructures for chemical and biological sensing.

AR Chandrasekaran,* H Wady & HKK Subramanian*
Small, 12: 2689 (2016). [PDF]

Beyond the fold: Emerging biological applications of DNA origami.

AR Chandrasekaran,* N Anderson, M Kizer, K Halvorsen & X Wang*
ChemBioChem, 17: 1081 (2016). [PDF]

A ‘tile’ tale: Hierarchical self-assembly of DNA lattices.

AR Chandrasekaran* & R Zhuo
Applied Materials Today, 2: 7 (2016). [PDF]

Programmable DNA scaffolds for spatially-ordered protein assembly.

AR Chandrasekaran*
Nanoscale, 8: 4436 (2016). [PDF]

DNA origami and biotechnology applications: A perspective.

AR Chandrasekaran*
Journal of Chemical Technology and Biotechnology, 91: 843 (2016). [PDF]

An update on nanomaterials‐based textiles for protection and decontamination.

S Sundarrajan, AR Chandrasekaran & S Ramakrishna
Journal of the American Ceramic Society, 93: 3955 (2010). [PDF]