A Biomimetic "Salting Out-Alignment-Locking" Tactic to Design Strong and Tough Hydrogel

Recently, hydrogel-based soft materials have demonstrated huge potential in soft robotics, flexible electronics as well as artificial skins. Although various methods are developed to prepare tough and strong hydrogels, it is still challenging to simultaneously enhance the strength and toughness of hydrogels, especially for protein-based hydrogels. Herein, a biomimetic "salting out-alignment-locking" tactic (SALT) is introduced for enhancing mechanical properties through the synergy of alignment and the salting out effect. As a typical example, tensile strength and modulus of initially brittle gelatin hydrogels increase 940 folds to 10.12 +/- 0.50 MPa and 2830 folds to 34.26 +/- 3.94 MPa, respectively, and the toughness increases up to 1785 folds to 14.28 +/- 3.13 MJ m-3. The obtained strength and toughness hold records for the previously reported gelatin-based hydrogel and are close to the tendons. It is further elucidated that the salting out effect engenders hydrophobic domains, while prestretching facilitates chain alignment, both synergistically contributing to the outstanding mechanical properties. It is noteworthy that the SALT demonstrates remarkable versatility across different salt types and polymer systems, thus opening up new avenues for engineering strong, tough, and stiff hydrogels. Inspired by the natural spider silk dragline producing process, a "salting out-alignment-locking" tactic (SALT) is developed in this paper. The obtained strength and toughness of gelatin hydrogels through SALT hold records for the previously reported gelatin-based hydrogel and are close to the tendons. The SALT also exhibits universality toward other salts and polymer systems. image