Protein-Based Hybrid Responsive Microparticles for Wound Healing

The in-depth development of biological materials, especially natural polymer materials, has injected strong vitality into clinical wound treatment. Here, a new type of controllable responsive microparticles composed of several natural polymer materials was presented for drug release and wound healing. These hybrid microparticles consisted of silk fibroin, gelatin, agarose, and black phosphorus quantum dots (BPQDs) and were loaded with growth factors and antibacterial peptides. Under near-infrared (NIR) irradiation, BPQDs could absorb the NIR light and increase the temperature of the microparticles to the melting point of gelatin. When the gelatin started to melt, the encapsulated drugs were gradually released because of the reversible phase transformation. Both in vitro and in vivo experiments have demonstrated that the BPQD-laden microparticles with a NIR-responsive feature could achieve the desired controllable release of growth factors to promote neovascularization formation. In addition, because antibacterial peptides were also mixed with the secondary hydrogel and encapsulated in the scaffolds, the microparticles are imparted with the antibacterial ability during storage and usage. These characteristics of BPQD-laden natural protein hybrid microparticles make them ideal for drug delivery and wound healing.

Automated summary

The development of controllable responsive microparticles composed of natural polymer materials, loaded with growth factors and antibacterial peptides, shows promising potential for drug release and wound healing applications. Under near-infrared (NIR) irradiation, these microparticles can achieve desired controllable release of growth factors to promote neovascularization formation. Additionally, the antibacterial peptides embedded in the microparticles provide antibacterial ability during storage and usage. These characteristics make the microparticles ideal for drug delivery and wound healing.