| Neutrophil-mediated anticancer drug delivery for suppression of postoperative malignant glioma recurrence J Xue, Z Zhao, L Zhang, L Xue, S Shen, Y Wen, Z Wei, L Wang, L Kong, ... Nature Nanotechnology 12 (7), 692-700, 2017 | 744 | 2017 |
| ATP-triggered anticancer drug delivery R Mo, T Jiang, R DiSanto, W Tai, Z Gu Nature Communications 5 (1), 3364, 2014 | 634 | 2014 |
| Enzyme-activatable polymer–drug conjugate augments tumour penetration and treatment efficacy Q Zhou, S Shao, J Wang, C Xu, J Xiang, Y Piao, Z Zhou, Q Yu, J Tang, ... Nature Nanotechnology 14 (8), 799-809, 2019 | 600 | 2019 |
| Emerging micro-and nanotechnology based synthetic approaches for insulin delivery R Mo, T Jiang, J Di, W Tai, Z Gu Chemical Society Reviews 43 (10), 3595-3629, 2014 | 442 | 2014 |
| Tumor microenvironment and intracellular signal-activated nanomaterials for anticancer drug delivery R Mo, Z Gu Materials Today 19 (5), 274-283, 2016 | 369 | 2016 |
| Cocoon-like self-degradable DNA nanoclew for anticancer drug delivery W Sun, T Jiang, Y Lu, M Reiff, R Mo, Z Gu Journal of the American Chemical Society 136 (42), 14722-14725, 2014 | 334 | 2014 |
| Gel–liposome‐mediated co‐delivery of anticancer membrane‐associated proteins and small‐molecule drugs for enhanced therapeutic efficacy T Jiang, R Mo, A Bellotti, J Zhou, Z Gu Advanced Functional Materials 24 (16), 2295-2304, 2014 | 319 | 2014 |
| Multistage pH‐responsive liposomes for mitochondrial‐targeted anticancer drug delivery R Mo, Q Sun, J Xue, N Li, W Li, C Zhang, Q Ping Advanced Materials 24 (27), 3659-3665, 2012 | 254 | 2012 |
| Sequential intra‐intercellular nanoparticle delivery system for deep tumor penetration C Ju, R Mo, J Xue, L Zhang, Z Zhao, L Xue, Q Ping, C Zhang Angewandte Chemie 126 (24), 6367-6372, 2014 | 244 | 2014 |
| Furin-mediated sequential delivery of anticancer cytokine and small-molecule drug shuttled by graphene T Jiang, W Sun, Q Zhu, NA Burns, SA Khan, R Mo, Z Gu Advanced Materials (Deerfield Beach, Fla.) 27 (6), 1021, 2015 | 237 | 2015 |
| Enhanced anticancer efficacy by ATP‐mediated liposomal drug delivery R Mo, T Jiang, Z Gu Angewandte Chemie 126 (23), 5925-5930, 2014 | 222 | 2014 |
| Enhanced transdermal drug delivery by transfersome-embedded oligopeptide hydrogel for topical chemotherapy of melanoma T Jiang, T Wang, T Li, Y Ma, S Shen, B He, R Mo ACS Nano 12 (10), 9693-9701, 2018 | 219 | 2018 |
| The mechanism of enhancement on oral absorption of paclitaxel by N-octyl-O-sulfate chitosan micelles R Mo, X Jin, N Li, C Ju, M Sun, C Zhang, Q Ping Biomaterials 32 (20), 4609-4620, 2011 | 214 | 2011 |
| ATP-responsive DNA-graphene hybrid nanoaggregates for anticancer drug delivery R Mo, T Jiang, W Sun, Z Gu Biomaterials 50, 67-74, 2015 | 176 | 2015 |
| A nanotherapeutic strategy to overcome chemotherapeutic resistance of cancer stem-like cells S Shen, X Xu, S Lin, Y Zhang, H Liu, C Zhang, R Mo Nature Nanotechnology 16 (1), 104-113, 2021 | 172 | 2021 |
| Bio-inspired synthetic nanovesicles for glucose-responsive release of insulin W Tai, R Mo, J Di, V Subramanian, X Gu, JB Buse, Z Gu Biomacromolecules 15 (10), 3495-3502, 2014 | 170 | 2014 |
| A collaborative assembly strategy for tumor-targeted siRNA delivery Q Sun, Z Kang, L Xue, Y Shang, Z Su, H Sun, Q Ping, R Mo, C Zhang Journal of the American Chemical Society 137 (18), 6000-6010, 2015 | 128 | 2015 |
| Tumor‐specific self‐degradable nanogels as potential carriers for systemic delivery of anticancer proteins Q Zhu, X Chen, X Xu, Y Zhang, C Zhang, R Mo Advanced Functional Materials 28 (17), 1707371, 2018 | 112 | 2018 |
| Endothelial ZEB1 promotes angiogenesis-dependent bone formation and reverses osteoporosis R Fu, WC Lv, Y Xu, MY Gong, XJ Chen, N Jiang, Y Xu, QQ Yao, L Di, T Lu, ... Nature Communications 11 (1), 460, 2020 | 110 | 2020 |
| Nanocomposite hydrogel incorporating gold nanorods and paclitaxel-loaded chitosan micelles for combination photothermal–chemotherapy N Zhang, X Xu, X Zhang, D Qu, L Xue, R Mo, C Zhang International journal of pharmaceutics 497 (1-2), 210-221, 2016 | 84 | 2016 |
