| Fatty acid membrane assembly on coacervate microdroplets as a step towards a hybrid protocell model TY Dora Tang, C Rohaida Che Hak, AJ Thompson, MK Kuimova, ... Nature chemistry 6 (6), 527-533, 2014 | 340 | 2014 |
| MaxSynBio: avenues towards creating cells from the bottom up P Schwille, J Spatz, K Landfester, E Bodenschatz, S Herminghaus, ... Angewandte Chemie International Edition 57 (41), 13382-13392, 2018 | 266 | 2018 |
| Compartmentalised RNA catalysis in membrane-free coacervate protocells B Drobot, JM Iglesias-Artola, K Le Vay, V Mayr, M Kar, M Kreysing, ... Nature communications 9 (1), 3643, 2018 | 256 | 2018 |
| Synthetic cellularity based on non-lipid micro-compartments and protocell models M Li, X Huang, TYD Tang, S Mann Current opinion in chemical biology 22, 1-11, 2014 | 180 | 2014 |
| Reversible pH‐responsive coacervate formation in lipid vesicles activates dormant enzymatic reactions C Love, J Steinkühler, DT Gonzales, N Yandrapalli, T Robinson, ... Angewandte Chemie 132 (15), 6006-6013, 2020 | 168 | 2020 |
| In vitro gene expression within membrane-free coacervate protocells TYD Tang, D Van Swaay, A DeMello, JLR Anderson, S Mann Chemical Communications 51 (57), 11429-11432, 2015 | 168 | 2015 |
| Gene-mediated chemical communication in synthetic protocell communities TYD Tang, D Cecchi, G Fracasso, D Accardi, A Coutable-Pennarun, ... ACS synthetic biology 7 (2), 339-346, 2018 | 142 | 2018 |
| Engineering bicontinuous cubic structures at the nanoscale—the role of chain splay CV Kulkarni, TY Tang, AM Seddon, JM Seddon, O Ces, RH Templer Soft Matter 6 (14), 3191-3194, 2010 | 102 | 2010 |
| Microfluidic formation of membrane‐free aqueous coacervate droplets in water D van Swaay, TYD Tang, S Mann, A de Mello Angewandte Chemie International Edition 54 (29), 8398-8401, 2015 | 83 | 2015 |
| Small-molecule uptake in membrane-free peptide/nucleotide protocells TYD Tang, M Antognozzi, JA Vicary, AW Perriman, S Mann Soft Matter 9 (31), 7647-7656, 2013 | 77 | 2013 |
| Can coacervation unify disparate hypotheses in the origin of cellular life? B Ghosh, R Bose, TYD Tang Current opinion in colloid & interface science 52, 101415, 2021 | 71 | 2021 |
| Non-equilibrium conditions inside rock pores drive fission, maintenance and selection of coacervate protocells A Ianeselli, D Tetiker, J Stein, A Kühnlein, CB Mast, D Braun, ... Nature chemistry 14 (1), 32-39, 2022 | 51 | 2022 |
| Cell-free gene expression dynamics in synthetic cell populations DT Gonzales, N Yandrapalli, T Robinson, C Zechner, TYD Tang ACS synthetic biology 11 (1), 205-215, 2022 | 47 | 2022 |
| Microfluidic formation of proteinosomes M Ugrinic, A Zambrano, S Berger, S Mann, TYD Tang, A Demello Chemical communications 54 (3), 287-290, 2018 | 47 | 2018 |
| Polynucleotides in cellular mimics: coacervates and lipid vesicles JR Vieregg, TYD Tang Current opinion in colloid & interface science 26, 50-57, 2016 | 45 | 2016 |
| Microfluidic tools for bottom-up synthetic cellularity M Ugrinic, A deMello, TYD Tang Chem 5 (7), 1727-1742, 2019 | 44 | 2019 |
| Charge-density reduction promotes ribozyme activity in RNA–peptide coacervates via RNA fluidization and magnesium partitioning JM Iglesias-Artola, B Drobot, M Kar, AW Fritsch, H Mutschler, ... Nature chemistry 14 (4), 407-416, 2022 | 42 | 2022 |
| Hydrostatic pressure effects on the lamellar to gyroid cubic phase transition of monolinolein at limited hydration TYD Tang, NJ Brooks, C Jeworrek, O Ces, NJ Terrill, R Winter, ... Langmuir 28 (36), 13018-13024, 2012 | 39 | 2012 |
| Spontaneous membrane-less multi-compartmentalization via aqueous two-phase separation in complex coacervate micro-droplets NG Moreau, N Martin, P Gobbo, TYD Tang, S Mann Chemical Communications 56 (84), 12717-12720, 2020 | 38 | 2020 |
| Quantitative theory for the diffusive dynamics of liquid condensates L Hubatsch, LM Jawerth, C Love, J Bauermann, TYD Tang, S Bo, ... Elife 10, e68620, 2021 | 34 | 2021 |
