Developing
multifunctional wound dressings, possessing not only
skin-like mechanical properties and adaptability, long-lasting moisture,
and temperature tolerance that maximally mimics the human skin but
also on-demand adhesion without unnecessary bleeding and secondary
damage upon peeling, is necessary but remains a challenge. Herein,
a novel dual cross-linked and multifunctional hydrogel, termed PSNC
hydrogel for polymerized sulfobetaine methacrylate (SBMA), N-(2-amino-2-oxyethyl)acrylamide (NAGA), and 1-carboxy-N-methyl-N-di(2-methacryloyloxy-ethyl)methanaminium
inner salt (CBMAX), was fabricated as a wound dressing for burn injuries
via one-pot radical polymerization in glycerine (GLY)/H2O solvent. The dual cross-linked network of the PSNC hydrogel combined
the double hydrogen bonding of N-(2-amino-2-oxyethyl)acrylamide
(NAGA) with a covalently cross-linked zwitterionic network, endowing
the hydrogel with skin–like mechanical properties with a high
stretchability of 1613.8 ± 79.8%, a tensile strength of 77.5
± 1.8 kPa, and a tensile modulus of 1.9 ± 0.1 kPa. Moreover,
the hydrogel with well-developed adaptability can withstand skin deformation
without breaking or debonding attributed to its good tissue adhesiveness
and self-healing ability. Further, the utilization of the GLY/H2O binary solvent effectively prevented the crystallization
and evaporation of free water, endowing the hydrogel with not only
long-lasting moisture but also excellent temperature tolerance in
a wide range from −20 to 60 °C. More importantly, the
PSNC hydrogel could effectively accelerate wound healing of burn injuries
and could be easily removed on-demand with saline without causing
secondary damage due to intense hydration. Such a novel PSNC zwitterionic
hydrogel could be a promising candidate for the treatment of burn
wounds and tissue regeneration.