Biological load-bearing tissues are strong, tough, and recoverable under periodic mechanical loads. However, such features have rarely been achieved simultaneously in the same synthetic hydrogels. Here, we use a force-coupled enzymatic reaction to tune a strong covalent peptide linkage to a reversible bond. Based on this concept we engineered double network hydrogels that combine high mechanical strength and reversible mechanical recovery in the same hydrogels. Specifically, we found that a peptide ligase, sortase A, can promote the proteolysis of peptides under force. The peptide bond can be re-ligated by the same enzyme in the absence of force. This allows the sacrificial network in the double-network hydrogels to be ruptured and rebuilt reversibly. Our results demonstrate a general approach for precisely controlling the mechanical and dynamic properties of hydrogels at the molecular level.
Keyphrases
- drug delivery
- hyaluronic acid
- tissue engineering
- single molecule
- drug release
- wound healing
- extracellular matrix
- hydrogen peroxide
- gene expression
- network analysis
- dna methylation
- hepatitis c virus
- genome wide
- brain injury
- human immunodeficiency virus
- electron transfer
- hiv infected
- endovascular treatment
- antiretroviral therapy