| Double‐network hydrogels with extremely high mechanical strength JP Gong, Y Katsuyama, T Kurokawa, Y Osada Advanced materials 15 (14), 1155-1158, 2003 | 4307 | 2003 |
| Why are double network hydrogels so tough? JP Gong Soft Matter 6 (12), 2583-2590, 2010 | 2096 | 2010 |
| Physical hydrogels composed of polyampholytes demonstrate high toughness and viscoelasticity TL Sun, T Kurokawa, S Kuroda, AB Ihsan, T Akasaki, K Sato, MA Haque, ... Nature materials 12 (10), 932-937, 2013 | 1818 | 2013 |
| Super tough double network hydrogels and their application as biomaterials MA Haque, T Kurokawa, JP Gong Polymer 53 (9), 1805-1822, 2012 | 766 | 2012 |
| High mechanical strength double‐network hydrogel with bacterial cellulose A Nakayama, A Kakugo, JP Gong, Y Osada, M Takai, T Erata, S Kawano Advanced functional materials 14 (11), 1124-1128, 2004 | 766 | 2004 |
| Soft and wet materials: polymer gels Y Osada, JP Gong Advanced materials 10 (11), 827-837, 1998 | 711 | 1998 |
| Large strain hysteresis and mullins effect of tough double-network hydrogels RE Webber, C Creton, HR Brown, JP Gong Macromolecules 40 (8), 2919-2927, 2007 | 699 | 2007 |
| Oppositely charged polyelectrolytes form tough, self-healing, and rebuildable hydrogels F Luo, TL Sun, T Nakajima, T Kurokawa, Y Zhao, K Sato, A Bin Ihsan, X Li, ... Advanced materials 27 (17), 2722-2727, 2015 | 609 | 2015 |
| Mechanoresponsive self-growing hydrogels inspired by muscle training T Matsuda, R Kawakami, R Namba, T Nakajima, JP Gong Science 363 (6426), 504-508, 2019 | 578 | 2019 |
| Tough physical double-network hydrogels based on amphiphilic triblock copolymers HJ Zhang, TL Sun, AK Zhang, Y Ikura, T Nakajima, T Nonoyama, ... Advanced Materials 28 (24), 4884-4890, 2016 | 485 | 2016 |
| Friction and lubrication of hydrogels—its richness and complexity JP Gong Soft matter 2 (7), 544-552, 2006 | 461 | 2006 |
| Materials both tough and soft JP Gong Science 344 (6180), 161-162, 2014 | 387 | 2014 |
| Lamellar bilayers as reversible sacrificial bonds to toughen hydrogel: hysteresis, self-recovery, fatigue resistance, and crack blunting MA Haque, T Kurokawa, G Kamita, JP Gong Macromolecules 44 (22), 8916-8924, 2011 | 384 | 2011 |
| Biomechanical properties of high-toughness double network hydrogels K Yasuda, JP Gong, Y Katsuyama, A Nakayama, Y Tanabe, E Kondo, ... Biomaterials 26 (21), 4468-4475, 2005 | 380 | 2005 |
| Determination of fracture energy of high strength double network hydrogels Y Tanaka, R Kuwabara, YH Na, T Kurokawa, JP Gong, Y Osada The Journal of Physical Chemistry B 109 (23), 11559-11562, 2005 | 337 | 2005 |
| True chemical structure of double network hydrogels T Nakajima, H Furukawa, Y Tanaka, T Kurokawa, Y Osada, JP Gong Macromolecules 42 (6), 2184-2189, 2009 | 333 | 2009 |
| A facile method to fabricate anisotropic hydrogels with perfectly aligned hierarchical fibrous structures MTI Mredha, YZ Guo, T Nonoyama, T Nakajima, T Kurokawa, JP Gong Advanced Materials 30 (9), 1704937, 2018 | 325 | 2018 |
| Stimuli-Responsive Polymer Gels and Their Application to Chemomechanical System Y Osada Prog. Polym. Sci. 18, 187-226, 1993 | 306 | 1993 |
| Synthesis of hydrogels with extremely low surface friction JP Gong, T Kurokawa, T Narita, G Kagata, Y Osada, G Nishimura, M Kinjo Journal of the American Chemical Society 123 (23), 5582-5583, 2001 | 289 | 2001 |
| Microgel-reinforced hydrogel films with high mechanical strength and their visible mesoscale fracture structure J Hu, K Hiwatashi, T Kurokawa, SM Liang, ZL Wu, JP Gong Macromolecules 44 (19), 7775-7781, 2011 | 287 | 2011 |
