Nanoengineered Supramolecular Adhesive Sponge for Rapid Hemostasis and Abdominal Wall Wound Healing.

Multifunctional dressing biomaterials that can promote tissue adhesion, hemostasis, and soft-tissue wound healing are of great clinical significance. Here, we report a nanocomposite supramolecular sponge constructed by an air-in-water emulsion template composed of methacrylated gelatin (GelMA), Laponite nanoclay, and branched supramolecular polymer (PAMU). The sponge has an interconnected macroporous structure and exhibits tunable mechanical properties with varying Laponite concentration. The nanoengineered sponge is endowed with tissue adhesion by intermolecular hydrogen bonds and ionic interactions contributed by the supramolecular polymer and the Laponite nanoclay. The biocompatible sponge facilitates cell proliferation and blood coagulation in both in vitro and in vivo experiments. In addition, the results of the rat external abdominal wall defect model show that the sponge can promote angiogenesis, collagen deposition, and granulation tissue formation to accelerate wound repair. These findings suggest that the unique air-in-water templated sponge is a promising candidate for applications in hemostasis and wound healing.

Macroporous Adhesive Nano-Enabled Hydrogels Generated from Air-in-Water Emulsions.

Developing nanocomposite hydrogel with multi-functions including adjustable mechanical property, tissue-adhesion, and blood coagulation property to accelerate wound healing is highly desirable in surgical application. Here a macroporous adhesive nano-enabled hydrogel constructed from gelatin methacryloyl stabilized air-in-water emulsions incorporated with dopamine-grafted-gelatin (GelDA) and Laponite nanoclay is reported. The hydrogel exhibits interconnected macroporous structure. The physical/chemical cross-linked network formed among the various components contributes to the good mechanical strength of hydrogel, which could be further regulated by adjusting the concentration of Laponite nanoclay. Furthermore, the nanocomposite macroporous hydrogel is endowed with self-healing properties and tissue adhesion by the intermolecular hydrogen bonds, ionic interactions among Laponite nanoclay and polymers, as well as the catechol functional groups. The in vitro studies demonstrate that the macroporous hydrogel has good biocompatibility and could significantly reduce blood clotting time, which is expected to be applied for the rapid sealing and hemostasis of bleeding wounds.