Hydro-Sensitive, In Situ Ultrafast Physical Self-Gelatinizing, and Red Blood Cells Strengthened Hemostatic Adhesive Powder with Antibiosis and Immunoregulation for Wound Repair.
Lingling ShangYonggan YanZhao LiHong LiuShaohua GeBaojin MaPublished in: Advanced science (Weinheim, Baden-Wurttemberg, Germany) (2023)
Immediate and effective hemostatic treatments for complex bleeding wounds are an urgent clinical demand. Hemostatic materials with characteristics of adhesion, sealing, anti-infection, and concrescence promotion have drawn growing concerns. However, pure natural multifunctional hemostatic materials with in situ ultrafast self-gelation are rarely reported. In this study, a hydro-sensitive collagen/tannic acid (ColTA) natural hemostatic powder is developed that can in situ self-gel to form adhesive by the non-covalent crosslinking between tannic acid (TA) and collagen (Col) in liquids. The physical interactions endow ColTA adhesive with the characteristics of instantaneous formation and high adhesion at various substrate surfaces. Crucially, ColTA powder adhesive shows an enhanced adhesion performance in the presence of blood due to the electrostatic interactions between ColTA adhesive and red blood cells, conducive to effective in situ sealing and rapid hemostasis. The biocompatible and hemocompatible ColTA adhesive can effectively control bleeding and seal the wounds of the caudal vein, liver, heart, and femoral arteries in rats. Furthermore, the low-cost and ready-to-use ColTA adhesive powder also possesses good antibacterial and inhibiting biofilm formation ability, and can efficiently regulate immune response by the NF-κB pathway to promote wound repair, making it a highly promising hemostatic material with great potential for biomedical applications.
Keyphrases
- biofilm formation
- red blood cell
- wound healing
- pseudomonas aeruginosa
- immune response
- staphylococcus aureus
- low cost
- escherichia coli
- candida albicans
- mental health
- atrial fibrillation
- drug delivery
- oxidative stress
- dendritic cells
- cystic fibrosis
- cancer therapy
- molecular dynamics simulations
- drug release
- pi k akt
- tissue engineering
- lps induced
- energy transfer
- silver nanoparticles