| Localized DNA hybridization chain reactions on DNA origami H Bui, S Shah, R Mokhtar, T Song, S Garg, J Reif ACS nano 12 (2), 1146-1155, 2018 | 130 | 2018 |
| Analog Computation by DNA Strand Displacement Circuits T Song, S Garg, R Mokhtar, H Bui, J Reif ACS Synthetic Biology 5 (8), 898-912, 2016 | 128 | 2016 |
| Design and Analysis of Localized DNA Hybridization Chain Reactions H Bui, V Miao, S Garg, R Mokhtar, T Song, J Reif small 13 (12), 2017 | 62 | 2017 |
| Renewable Time‐Responsive DNA Circuits S Garg, S Shah, H Bui, T Song, R Mokhtar, J Reif Small 14 (33), 1801470, 2018 | 56 | 2018 |
| Programming DNA-based biomolecular reaction networks on cancer cell membranes T Song, S Shah, H Bui, S Garg, A Eshra, D Fu, M Yang, R Mokhtar, J Reif Journal of the American Chemical Society 141 (42), 16539-16543, 2019 | 53 | 2019 |
| Improving the performance of DNA strand displacement circuits by shadow cancellation T Song, N Gopalkrishnan, A Eshra, S Garg, R Mokhtar, H Bui, ... ACS nano 12 (11), 11689-11697, 2018 | 41 | 2018 |
| Design and analysis of compact DNA strand displacement circuits for analog computation using autocatalytic amplifiers T Song, S Garg, R Mokhtar, H Bui, J Reif ACS synthetic biology 7 (1), 46-53, 2018 | 40 | 2018 |
| Design and analysis of linear cascade DNA hybridization chain reactions using DNA hairpins H Bui, S Garg, V Miao, T Song, R Mokhtar, J Reif New Journal of Physics 19 (1), 015006, 2017 | 18 | 2017 |
| Directed enzymatic activation of 1-d DNA tiles S Garg, H Chandran, N Gopalkrishnan, TH LaBean, J Reif ACS nano 9 (2), 1072-1079, 2015 | 6 | 2015 |
| Modeling DNA Nanodevices Using Graph Rewrite Systems R Mokhtar, S Garg, H Chandran, H Bui, T Song, J Reif Advances in Unconventional Computing, 347-395, 2017 | 4 | 2017 |
| Nucleic acid hairpins: A robust and powerful motif for molecular devices S Garg, H Bui, A Eshra, S Shah, J Reif World Scientific Series in Nanoscience and Nanotechnology 19, 175, 2019 | 3 | 2019 |
| Programming Molecular Devices using Nucleic Acid Hairpins S Garg | 3 | 2016 |
| A graph rewriting system for modeling DNA nanodevices R Mokhtar, S Garg, H Chandran, H Bui, T Song, J Reif DNA 4 (26), 29-31, 2013 | 1 | 2013 |
| Biomolecular Computing Systems H Chandran, S Garg, N Gopalkrishnan, J Reif Organization 11 (ISBN: 978-3-527-33228-1), 1, 2012 | 1 | 2012 |
| Activatable Tiles: Demonstration of Linear and Directed Self Assembly H Chandran, S Garg, N Gopalkrishnan, J Reif FNANO2012. Full paper under preparation, 108, 2012 | 1 | 2012 |
| Speeding up DNA circuits using localized hybridization N Gopalkrishnan, H Chandran, S Garg, J Reif Foundations of Nanoscience Meeting (FNANO), 2011 | 1 | 2011 |
| Activatable tiles for compact robust programmable molecular assembly and other applications U Majumder, S Garg, TH LaBean, JH Reif Natural Computing 15 (4), 611-634, 2016 | | 2016 |
| DNA Computing H Bui, H Chandran, S Garg, N Gopalkrishnan, R Mokhtar, JH Reif, T Song | | 2014 |
| One-Time, Directed and Catalytic Activation of 1-D DNA Tiles S Garg, H Chandran, N Gopalkrishnan, J Reif | | 2012 |
| Self-Replicating DNA Nanostructures: Autocatalytic Nanodevices derived from Catalytic Nanodevices S Garg, N Gopalkrishnan, H Chandran, J Reif | | |
John ReifA. Hollis Edens Distinguished Professor, Department of Computer Science, Duke UniversityVerified email at cs.duke.edu
