| j5 DNA assembly design automation software NJ Hillson, RD Rosengarten, JD Keasling ACS synthetic biology 1 (1), 14-21, 2012 | 388 | 2012 |
| The Synthetic Biology Open Language (SBOL) provides a community standard for communicating designs in synthetic biology M Galdzicki, KP Clancy, E Oberortner, M Pocock, JY Quinn, CA Rodriguez, ... Nature biotechnology 32 (6), 545-550, 2014 | 315 | 2014 |
| A Cas9-based toolkit to program gene expression in Saccharomyces cerevisiae A Reider Apel, L d'Espaux, M Wehrs, D Sachs, RA Li, GJ Tong, M Garber, ... Nucleic acids research 45 (1), 496-508, 2017 | 255 | 2017 |
| De novo DNA synthesis using polymerase-nucleotide conjugates S Palluk, DH Arlow, T De Rond, S Barthel, JS Kang, R Bector, ... Nature biotechnology 36 (7), 645-650, 2018 | 253 | 2018 |
| Building a global alliance of biofoundries N Hillson, M Caddick, Y Cai, JA Carrasco, MW Chang, NC Curach, ... Nature communications 10 (1), 2040, 2019 | 249 | 2019 |
| Yersiniabactin synthetase: a four-protein assembly line producing the nonribosomal peptide/polyketide hybrid siderophore of Yersinia pestis DA Miller, L Luo, N Hillson, TA Keating, CT Walsh Chemistry & biology 9 (3), 333-344, 2002 | 244 | 2002 |
| Design, implementation and practice of JBEI-ICE: an open source biological part registry platform and tools TS Ham, Z Dmytriv, H Plahar, J Chen, NJ Hillson, JD Keasling Nucleic acids research 40 (18), e141-e141, 2012 | 225 | 2012 |
| Principal component analysis of proteomics (PCAP) as a tool to direct metabolic engineering J Alonso-Gutierrez, EM Kim, TS Batth, N Cho, Q Hu, LJG Chan, ... Metabolic engineering 28, 123-133, 2015 | 190 | 2015 |
| High-throughput identification of transcription start sites, conserved promoter motifs and predicted regulons PT McGrath, H Lee, L Zhang, AA Iniesta, AK Hottes, MH Tan, NJ Hillson, ... Nature biotechnology 25 (5), 584-592, 2007 | 182 | 2007 |
| Machine learning for metabolic engineering: A review CE Lawson, JM Martí, T Radivojevic, SVR Jonnalagadda, R Gentz, ... Metabolic Engineering 63, 34-60, 2021 | 178 | 2021 |
| Engineering of Ralstonia eutropha H16 for autotrophic and heterotrophic production of methyl ketones J Mï¿ ½ller, D MacEachran, H Burd, N Sathitsuksanoh, C Bi, YC Yeh, ... Applied and environmental microbiology 79 (14), 4433-4439, 2013 | 167 | 2013 |
| Pressure-induced protein-folding/unfolding kinetics N Hillson, JN Onuchic, AE García Proceedings of the National Academy of Sciences 96 (26), 14848-14853, 1999 | 142 | 1999 |
| Development of a broad-host synthetic biology toolbox for Ralstonia eutropha and its application to engineering hydrocarbon biofuel production C Bi, P Su, J Müller, YC Yeh, SR Chhabra, HR Beller, SW Singer, ... Microbial cell factories 12, 1-10, 2013 | 140 | 2013 |
| Lessons from Two Design–Build–Test–Learn Cycles of Dodecanol Production in Escherichia coli Aided by Machine Learning P Opgenorth, Z Costello, T Okada, G Goyal, Y Chen, J Gin, V Benites, ... ACS synthetic biology 8 (6), 1337-1351, 2019 | 132 | 2019 |
| Scar-less multi-part DNA assembly design automation NJ Hillson US Patent 9,361,427, 2016 | 119 | 2016 |
| Droplet microfluidics for synthetic biology PC Gach, K Iwai, PW Kim, NJ Hillson, AK Singh Lab on a Chip 17 (20), 3388-3400, 2017 | 116 | 2017 |
| DeviceEditor visual biological CAD canvas J Chen, D Densmore, TS Ham, JD Keasling, NJ Hillson Journal of biological engineering 6, 1-12, 2012 | 114 | 2012 |
| Catalytic mapping of the vibriobactin biosynthetic enzyme VibF CG Marshall, NJ Hillson, CT Walsh Biochemistry 41 (1), 244-250, 2002 | 113 | 2002 |
| A versatile microfluidic device for automating synthetic biology SCC Shih, G Goyal, PW Kim, N Koutsoubelis, JD Keasling, PD Adams, ... ACS synthetic biology 4 (10), 1151-1164, 2015 | 111 | 2015 |
| SBOL visual: a graphical language for genetic designs JY Quinn, RS Cox III, A Adler, J Beal, S Bhatia, Y Cai, J Chen, K Clancy, ... PLoS biology 13 (12), e1002310, 2015 | 91 | 2015 |
