able to create a beak that possesses steep mechanical gradients with stiffness differences of two orders of magnitude occurring over centimeter-length scales. [1,2] Further, the mantis shrimp saddle is spatially organized with a highly mineralized outer layer that imparts stiffness, and a chitin-protein inner layer that confers flexibility. [3,4] In addition to synthesizing static structures, biology is also capable of creating the dynamic material systems that are needed for living systems to reconfigure during complex developmental programs (insect metamorphosis) [5] ; remodel for wound healing [6,7] ; and match properties to disparate functional needs (e.g., the lubricating and shock-absorbing properties of synovial fluid). [8] In many cases, biology creates such dynamic material systems using polymeric networks that are cross-linked through reversible physical interactions that can respond to local stimuli, [9] heal, [10][11][12] and balance the needs for strength and plasticity. [1,2,13,14] For instance, the electrostatic interactions between Ca 2+ and collagen act as sacrificial bonds to prevent brittle fracture in bone, [13,14] while domains in the titin protein that can reversibly unfold may allow muscles to withstand large deformations. [9] This emerging understanding of biological materials is also inspiring the development of high-performance technological materials. For instance, the mussel byssus illustrates the importance of coupling cross-linking mechanisms, as it uses covalent cross-links to confer strength and structural memory (i.e., elasticity) and reversible metal coordination bonds to confer the toughness and self-healing capabilities required to withstand what would seem to be nonrecoverable deformations. [10][11][12] There is growing interest in applying such a dual cross-linking strategy to fabricate high-toughness materials. A common technological approach is to use two interpenetrating polymeric networks that are individually cross-linked through separate mechanisms. [15][16][17][18][19][20][21][22][23] One network is cross-linked through strong (often covalent) bonds that confer elasticity, while the second network is cross-linked through weaker (often physical) interactions that can be broken and reformed in ways that dissipate mechanical energy to confer toughness to the dual polymeric network. [18,24] Alternative technological approaches to introduce energy-dissipating capabilities to materials include the use of nanocomposites [25][26][27] and phase-separated gels, [28] as well as topological gels (e.g., double networks, [16,29] slide-ring gels, [30] Biology uses various cross-linking mechanisms to tailor material properties, and this is inspiring technological efforts to couple independent crosslinking mechanisms to create hydrogels with complex mechanical properties. Here, it is reported that a hydrogel formed from a single polysaccharide can be triggered to reversibly switch cross-linking mechanisms and switch between elastic and viscoelastic properties. Specifically, the pH-resp...
