Abstract:Chronic wound healing is a major challenge in clinical practice. Secondary dressing damage and antibiotic resistance are the main obstacles for traditional wound dressings. Resina draconis (RD), a natural resin traditionally used in powder form for wound care, is now considered unsuitable due to the lack of gas permeability and moist environment required for wound healing. Here, RD is incorporated in situ by constructing a 3D coiled fibrous scaffold with polycaprolactone/polyethylene oxide. Due to the high porosity of 3D scaffold, the RD‐3D dressings have a favorable swelling capacity, providing permeability and moisture for wound repair. Meanwhile, the transformation of RD powder into 3D dressings fully demonstrates capabilities of RD in rapid hemostasis, bactericidal, and inflammation‐regulating activities. In vivo evaluations using pressure ulcer and infected wound models confirm the high efficacy of RD‐3D dressing in early wound healing, particularly beneficial in the infected wound model compared to recombinant bovine FGF‐basic. Further biological analysis shows that resveratrol, loureirin A, and loureirin B, as potentially bioactive components of RD, individually contribute to different aspects of wound healing. Collectively, RD‐3D integrated dressings represent a simple, cost‐effective, and safe approach to wound healing, providing an alternative therapy for translating medical dressings from bench to bedside.