Transplanted artificial amnion membrane enhanced wound healing in third-degree burn injury diabetic mouse model.

Introduction: Wound healing is severely compromised in patients with diabetes owing to factors such poor blood circulation, delayed immune response, elevated blood sugar levels, and neuropathy. Although the development of new wound healing products and prevention of serious complications such as infections in wounds have received substantial interest, wound healing remains a challenge in regenerative medicine. Burn wounds, especially third-degree burns, are difficult to treat because they are associated with immune and inflammatory reactions and distributive shock. Wound care and treatment that protects the burn site from infection and allows wound healing can be achieved with bioengineered wound dressings. However, few studies have reported effective dressings for third-degree burn wounds, making it important to develop new dressing materials. Methods: In this study, we developed an artificial amniotic membrane (AM) using epithelial and mesenchymal cells derived from human amnion as a novel dressing material. The artificial AM was applied to the wound of a diabetic third-degree burn model and its wound healing ability was evaluated. Results: This artificial amnion produced multiple growth factors associated with angiogenesis, fibroblast proliferation, and anti-inflammation. In addition, angiogenesis and granulation tissue formation were promoted in the artificial AM-treated mouse group compared with the control group. Furthermore, the inflammatory phase was prolonged in the control group. Conclusions: Our preliminary results indicate that the artificial AM might be useful as a new dressing for refractory ulcers and third-degree burns. This artificial AM-based material represents great potential for downstream clinical research and treatment of diabetes patients with third-degree burns.

Importance of Housekeeping Gene Optimization for the Analysis of mRNA Expression During Wound Healing in a Third-Degree Burn Injury Model.

Wound healing evaluation methods in a third-degree burn injury model are categorized as histological (re-epithelialization and granulation tissue formation) and molecular (quantitative polymerase chain reaction). In general, mRNA expression is normalized to those of the housekeeping gene. Although the housekeeping gene expression is generally stable, it has been reported that the stability of these genes depends on the wound healing process and treatment method. In this study, we identified the most stable housekeeping gene (TATA-binding protein) for studying gene expression in a third-degree burn injury model, in which wound healing was promoted by grafting human amnion-derived mesenchymal cells. We investigated the wound healing effect of human amnion-derived mesenchymal cells in the injury model. The formation of granulation tissue, the differentiation from fibroblasts to myofibroblasts, and functional vascular structure were promoted in the full-thickness skin excision site by treatment with these cells. The expression of angiogenic, pro-inflammatory and anti-inflammatory related mRNA was measured and normalized to that of the housekeeping gene, showing that treatment with the cells promoted the infiltration of endothelial cells and differentiation of M1 and M2 macrophages. In conclusion, wound healing in a third-degree burn injury model can be accurately analyzed using the optimized housekeeping gene.

Hyperdry human amniotic membrane is useful material for tissue engineering: physical, morphological properties, and safety as the new biological material.

Human amniotic membrane (AM) has been used widely as graft biomaterial for a variety of clinical applications. But, there are some persistent problems related to the preparation, storage, and sterilization. To resolve these problems, we developed hyperdry AM (HD-AM) using far-infrared rays, depression of air, and microwaves and then sterilized by γ-ray irradiation. To elucidate the benefit of HD-AM as biological materials, compare with the physical and histological properties of HD-AM with a freeze-dried AM (FD-AM) as typical freeze-dried methods, evaluate the safety of HD-AM in vivo experiment used nude mice, and demonstrate the feasibility of HD-AM transplant in pterygium. The water permeability and the sieving coefficient of HD-AM were significantly lower than that of FD-AM. HD-AM has kept the morphological structure of epithelium and connective tissues. At 18 months after transplanted, single and multilayers of HD-AM in the intraperitoneal cavity was degraded without any infiltrated cells. For clinical treatment, recurrence of pterygium and regrowth of the subconjunctival fibrosis were not observed during the 6-month follow-up periods after the surgery. It was proposed that HD-AM was a safe and effective new biological material for clinical use including treatment for recurrent pterygium.