| DNA sequence–directed shape change of photopatterned hydrogels via high-degree swelling A Cangialosi, CK Yoon, J Liu, Q Huang, J Guo, TD Nguyen, DH Gracias, ... Science 357 (6356), 1126-1130, 2017 | 418 | 2017 |
| An information-bearing seed for nucleating algorithmic self-assembly RD Barish, R Schulman, PWK Rothemund, E Winfree Proceedings of the National Academy of Sciences 106 (15), 6054-6059, 2009 | 302 | 2009 |
| Synthesis of crystals with a programmable kinetic barrier to nucleation R Schulman, E Winfree Proceedings of the National Academy of Sciences 104 (39), 15236-15241, 2007 | 210 | 2007 |
| Electrostatic-driven lamination and untwisting of β-sheet assemblies Y Hu, R Lin, P Zhang, J Fern, AG Cheetham, K Patel, R Schulman, C Kan, ... ACS nano 10 (1), 880-888, 2016 | 152 | 2016 |
| Robust self-replication of combinatorial information via crystal growth and scission R Schulman, B Yurke, E Winfree Proceedings of the national academy of sciences 109 (17), 6405-6410, 2012 | 140 | 2012 |
| The living interface between synthetic biology and biomaterial design AP Liu, EA Appel, PD Ashby, BM Baker, E Franco, L Gu, K Haynes, ... Nature materials 21 (4), 390-397, 2022 | 122 | 2022 |
| Directing self-assembly of DNA nanotubes using programmable seeds AM Mohammed, R Schulman Nano letters 13 (9), 4006-4013, 2013 | 109 | 2013 |
| Building in vitro transcriptional regulatory networks by successively integrating multiple functional circuit modules SW Schaffter, R Schulman Nature chemistry 11 (9), 829-838, 2019 | 102 | 2019 |
| Modular DNA strand-displacement controllers for directing material expansion J Fern, R Schulman Nature Communications 9 (1), 3766, 2018 | 97 | 2018 |
| Self-assembling DNA nanotubes to connect molecular landmarks AM Mohammed, P Šulc, J Zenk, R Schulman Nature nanotechnology 12 (4), 312-316, 2017 | 91 | 2017 |
| DNA strand-displacement timer circuits J Fern, D Scalise, A Cangialosi, D Howie, L Potters, R Schulman ACS synthetic biology 6 (2), 190-193, 2017 | 85 | 2017 |
| Reducing facet nucleation during algorithmic self-assembly HL Chen, R Schulman, A Goel, E Winfree Nano Letters 7 (9), 2913-2919, 2007 | 80 | 2007 |
| Programmable control of nucleation for algorithmic self-assembly R Schulman, E Winfree International Workshop on DNA-Based Computers, 319-328, 2004 | 73 | 2004 |
| Programmable control of nucleation for algorithmic self-assembly R Schulman, E Winfree SIAM Journal on Computing 39 (4), 1581-1616, 2010 | 67 | 2010 |
| Designing modular reaction-diffusion programs for complex pattern formation D Scalise, R Schulman Technology 2 (01), 55-66, 2014 | 58 | 2014 |
| Controlling matter at the molecular scale with DNA circuits D Scalise, R Schulman Annual review of biomedical engineering 21 (1), 469-493, 2019 | 57 | 2019 |
| Self-assembly of hierarchical DNA nanotube architectures with well-defined geometries TD Jorgenson, AM Mohammed, DK Agrawal, R Schulman ACS nano 11 (2), 1927-1936, 2017 | 55 | 2017 |
| Self-assembly of precisely defined DNA nanotube superstructures using DNA origami seeds AM Mohammed, L Velazquez, A Chisenhall, D Schiffels, DK Fygenson, ... Nanoscale 9 (2), 522-526, 2017 | 45 | 2017 |
| Emulating cellular automata in chemical reaction–diffusion networks D Scalise, R Schulman Natural Computing 15, 197-214, 2016 | 43 | 2016 |
| Kinetics and thermodynamics of Watson–Crick base pairing driven DNA origami dimerization J Zenk, C Tuntivate, R Schulman Journal of the American Chemical Society 138 (10), 3346-3354, 2016 | 43 | 2016 |
