Protease-Mediated Recovery of Amnion from Placenta and Its Application as a Bioprocessed Therapeutic Biomaterial for Wound Healing
Abstract
Material and Methods: The enzymatic treatment effectively removes non-collagenous proteins and epithelial layers, creating high-quality amnion suitable for wound-healing applications. Biophysical characterization of the biomaterials demonstrated suitable tensile strength, permeability to oxygen and water vapor, and high surface area, all critical for effective wound coverage and healing.
Results: In vitro studies showed that amnion scaffolds promoted fibroblast proliferation with low toxicity and high biocompatibility, while in vivo rat models indicated significantly faster wound healing, with complete closure observed in 7 days compared to 12–14 days for controls. Histological analysis confirmed enhanced collagen organization and skin structure regeneration in treated wounds.
Conclusion: These results demonstrate that enzymatically processed amnion scaffolds are an effective and cost-efficient alternative for wound care, with superior healing outcomes compared to conventional therapies. This study supports the use of amnion-derived biomaterials in treating chronic wounds, including diabetic and venous leg ulcers.
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