Niosome-Based Hydrogel of Quince Extract: A Promising Strategy for Expedited Full-thickness Wound Healing in Rat.

Pedram Ebrahimnejad, Paria Fadaee Heydarabadi, Fereshteh Talebpour Amiri, Fatemeh Mirzaee, Melika Ahmadi, Somayeh Shahani
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Abstract

Background: The regeneration of tissue damage involves a series of molecular and cellular events that can be mediated by various natural compounds. Recent studies have highlighted the anti-inflammatory, anti-ulcer, and skin-protecting properties of Cydonia oblonga (Quince), which are mainly attributed to phenolic compounds. These compounds may have some drawbacks when targeting wound applications, including low bioavailability at the wound site. Moreover, to overcome these limitations, surfactant-based nanovesicular systems have been developed as carriers of such compounds for wound healing.

Objective: This study aimed to highlight the possible therapeutic potential of niosome-based hydrogel from Quince extract to stabilize and deliver the related bioactive compounds to full-thickness wounds in rats.

Methods: The niosomal hydrogel was prepared using a thin-film hydration method with the fruit extract (70% methanol). The formulation was optimized by evaluating size, zeta potential, dispersion index, and drug encapsulation efficiency. Full-thickness wounds were created on the dorsal cervical area of Wistar rats, and histopathological analysis of biopsy specimens was conducted on the 12th day of treatment.

Results: Under the study conditions, niosomal hydrogel displayed good physicochemical stability. Histopathological findings demonstrated that niosomal gel promoted angiogenesis, fibroblast maturation, collagen deposition, keratinization, and epidermal layer formation more effectively than control and hydrogel base. Furthermore, niosomal gel treatment markedly reduced inflammation. The total phenol concentration was determined to be 13.34 ± 0.90 mg gallic acid equivalents per gram of dried extract.

Conclusion: The niosomal hydrogel containing C. oblonga extract shows potential as a novel approach for wound healing, warranting further investigation in this field.

基于榅桲提取物的水凝胶:加速大鼠全厚伤口愈合的有效策略
背景:组织损伤的再生涉及一系列分子和细胞事件,这些事件可由各种天然化合物介导。最近的研究强调了榅桲(Cydonia oblonga)的抗炎、抗溃疡和皮肤保护特性,这些特性主要归因于酚类化合物。这些化合物在针对伤口应用时可能存在一些缺点,包括在伤口部位的生物利用率较低。此外,为了克服这些局限性,人们开发了基于表面活性剂的纳米囊泡系统,作为此类化合物的载体,用于伤口愈合:本研究旨在强调从榅桲提取物中提取的基于niosome的水凝胶可能具有的治疗潜力,以稳定相关生物活性化合物并将其输送到大鼠的全厚伤口中:方法:采用薄膜水合法,用榅桲提取物(70%甲醇)制备榅桲水凝胶。通过评估尺寸、ZETA电位、分散指数和药物封装效率,对配方进行了优化。在 Wistar 大鼠的颈背部位造成全厚伤口,并在治疗的第 12 天对活检标本进行组织病理学分析:结果:在研究条件下,水凝胶具有良好的理化稳定性。组织病理学研究结果表明,与对照组和水凝胶基质相比,尼泊金凝胶能更有效地促进血管生成、成纤维细胞成熟、胶原沉积、角质化和表皮层形成。此外,尼索米尔凝胶还能明显减轻炎症反应。经测定,每克干燥提取物的总酚浓度为 13.34 ± 0.90 毫克没食子酸当量:含有 C. oblonga 提取物的透明质水凝胶显示出作为伤口愈合新方法的潜力,值得在该领域开展进一步研究。
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