Improved Wound Closure Rates and Mechanical Properties Resembling Native Skin in Murine Diabetic Wounds Treated with a Tropoelastin and Collagen Wound Healing Device

R. Kellar, Robert B. Diller, A. Tabor, Dominic Dominguez, R. Audet, Tatum A. Bardsley, Alyssa J. Talbert, Nathan Cruz, Alison L. Ingraldi, B. Ensley
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引用次数: 4

Abstract

Chronic wounds in patients suffering from type II diabetes mellitus (DMII) where wounds remain open with a complicated pathophysiology, healing, and recovery process is a public health concern. Normal wound healing plays a critical role in wound closure, restoration of mechanical properties, and the biochemical characteristics of the remodeled tissue. Biological scaffolds provide a tissue substitute to help facilitate wound healing by mimicking the extracellular matrix (ECM) of the dermis. In the current study an electrospun biomimetic scaffold, wound healing device (WHD), containing tropoelastin (TE) and collagen was synthesized to mimic the biochemical and mechanical characteristics of healthy human skin. The WHD was compared to a commercially available porcine small intestinal submucosa (SIS) matrix that has been used in both partial and full-thickness wounds, Oasis® Wound Matrix. Wound closure rates, histochemistry, qPCR, and mechanical testing of treated wound sites were evaluated. The WHD in a splinted, full-thickness, diabetic murine wound healing model demonstrated an enhanced rate of wound closure, decreased tissue inflammation, skin organ regeneration, and a stronger and more durable remodeled tissue that more closely mimics native unwounded skin compared to the control device.
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用滋养剂和胶原伤口愈合装置治疗小鼠糖尿病伤口,伤口闭合率和力学性能与天然皮肤相似
2型糖尿病(DMII)患者的慢性伤口开放性具有复杂的病理生理、愈合和恢复过程,是一个公共卫生问题。正常的创面愈合在创面闭合、机械性能的恢复以及重建组织的生化特性等方面起着至关重要的作用。生物支架通过模拟真皮层的细胞外基质(ECM),提供了一种组织替代品,有助于促进伤口愈合。本研究合成了一种含有对弹力蛋白和胶原蛋白的电纺仿生支架——伤口愈合装置(WHD),以模拟健康人体皮肤的生化和力学特性。将WHD与市售的用于部分和全层伤口的猪小肠黏膜下层(SIS)基质Oasis®Wound matrix进行比较。评估伤口愈合率、组织化学、qPCR和处理伤口部位的力学测试。与对照装置相比,在一个固定的、全层的糖尿病小鼠伤口愈合模型中,WHD显示出伤口愈合率提高、组织炎症减少、皮肤器官再生,以及更强、更持久的重塑组织,更接近于原生未受伤皮肤。
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