Abstract
Injectable behavior is often observed in polymer-based hydrogels yet is rarely achieved in low-molecular-weight hydrogels (LMWHs), the realization of which may boost the development of new soft materials for biomedical applications. Here, we report on injectable self-healing and antidissolving LMWHs that are formed through a simple ionic cross-linking strategy, showing a fundamental application for the encapsulation of living cells. The LMWHs are formed by simply mixing Ca2+ with negatively charged supramolecular polymers. Surprisingly, the resultant hydrogels are capable of rapidly self-healing within seconds after damage, showing an unexpected injectable function. When the hydrogel is injected into an aqueous medium, continuous macroscopic hydrogel fibers can be produced. Interestingly, the hydrogel can remain intact in the aqueous medium, showing impressive antidissolving behavior which is less observed in other LMWHs. Furthermore, the hydrogel is demonstrated to be nontoxic and can be used as a cytocompatible scaffold for living cells. This work may open an avenue toward injectable and antidissolving LMWHs for the ever-expanding list of applications in biotherapy and bioprinting.
Published Version
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