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Ethyl-Cellulose Nanosponges for Topical Delivery of Simvastatin with Preferential Skin Retention for Wound Healing in a Full-Thickness Wound Rat Model

Samar Aboelazayem, Maha M. A. Nasra, Heba M. K. Ebada, Ossama Y. Abdallah

2025AAPS PharmSciTech9 citationsDOIOpen Access PDF

Abstract

Abstract Novel topical nanosponges were implemented to improve the skin availability of simvastatin (SV) for treating full-thickness wounds while controlling the scarring process. SV exhibits great potential in treating various skin diseases owing to its antibacterial, antioxidant, anti-inflammatory, and immunomodulatory properties. However, its poor oral bioavailability and systemic side effects have hindered its clinical application in dermatology. For the first time, nanosponges were utilized to target injured skin, creating an SV reservoir within the wound bed to enhance therapeutic efficacy while minimizing adverse effects. Herein, SV-loaded ethyl-cellulose nanosponges (SV-NS) were prepared using the emulsion solvent evaporation technique, optimizing organic solvents, SV concentration, and stabilizer concentration. The selected SV-NS (20 mg SV) exhibited nanoporous particles (786.2 ± 50 nm), a specific surface area of 10.3 m 2 /g, and a total pore volume of 0.016 cm 3 /g, offering sustained release and enhanced skin retention capacity. In vivo studies on full-thickness rat wounds confirmed that topical SV-NS (5 mg SV, applied every 5 days) significantly accelerated wound closure ( P < 0.0001), achieving 76.23 ± 3.20% closure by day 8, a 47% improvement over free SV. Consequently, SV-NS facilitated wound closure exceeding 90% by day 11, whereas free SV required 16 days to attain a comparable level, representing a 31.2% faster healing rate. Histological analysis further revealed that SV-NS promoted optimal epidermal layer formation and well-organized collagen deposition, with collagen expression significantly ( P < 0.0001) reaching 59.85 ± 3.17% by day 16. Conclusively, SV-NS enhances SV’s dermal availability, improving wound healing and minimizing side effects, demonstrating a promising approach for wound restoration. Graphical Abstract

Topics & Concepts

SimvastatinBioavailabilityWound healingEthyl celluloseChemistryEmulsionPoloxamerIn vivoPharmacologyBiomedical engineeringMedicineSurgeryBiochemistryOrganic chemistryBiologyBiotechnologyCopolymerPolymerWound Healing and TreatmentsAdvancements in Transdermal Drug DeliveryTendon Structure and Treatment
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