Engineered bacterial cellulose-based Ag nanoparticles/g-C3N4/Eucalyptus extract nanocomposites for wound dressing: In vitro evaluation

Maral Sorourian , Mehrab Pourmadadi , Fatemeh Yazdian , Hamid Rashedi , Mona Navaei Nigjeh , Ghazal Sorourian , Abbas Rahdar , Sadanand Pandey
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Abstract

In recent years, antibacterial wound dressings have gained considerable attention. Bacterial cellulose (BC) has received significant interest due to its unique physiochemical characteristics such as biocompatibility, high porosity, superior mechanical properties, water holding capacity, and nontoxicity. In this work, silver nanoparticles/graphitic carbon nitride/eucalyptus extract (Ag/gCN/EE) nanocomposite was synthesized as an antibacterial agent and incorporated into nanofibrous structures composed of BC. The BC/Ag/gCN/EE and polyvinyl alcohol/BC/Ag/gCN/EE (PVA/BC/Ag/gCN/EE) nanocomposites were synthesized using immersion and electrospinning methods, respectively. Then, the swelling ratio was optimized and the wound dressings were prepared based on the optimal formulation. The release profile, biodegradability and mechanical properties of the wound dressings were assessed. The antibacterial property of Ag/gCN/EE was studied demonstrating strong antibacterial activity on E. coli and S. aureus. MTT assay was carried out on NIH 3T3 fibroblast cells, and BC/Ag/gCN/EE and PVA/BC/Ag/gCN/EE nanocomposites showed 89 ± 2.31 % and 96 ± 3.28 % viability, respectively and no toxicity. To assess the effect of the composites on in vitro wound healing and cell migration, scratch wound assay was performed. The results indicated that after 24 h, BC/Ag/gCN/EE and PVA/BC/Ag/gCN/EE reduced 18.69 and 23.97 % of the scratch area compared to the control group. The prepared composites are promising wound dressings that could accelerate wound healing and kill bacteria simultaneously.

Abstract Image

用于伤口敷料的细菌纤维素基银离子纳米颗粒/g-C3N4/桉树提取物纳米复合材料:体外评估
近年来,抗菌伤口敷料备受关注。细菌纤维素(BC)因其独特的理化特性,如生物相容性、高孔隙率、优异的机械性能、持水能力和无毒性,受到了广泛关注。在这项工作中,合成了银纳米粒子/石墨氮化碳/桉树提取物(Ag/gCN/EE)纳米复合材料作为抗菌剂,并将其加入到由 BC 组成的纳米纤维结构中。采用浸泡法和电纺丝法分别合成了 BC/Ag/gCN/EE 和聚乙烯醇/BC/Ag/gCN/EE(PVA/BC/Ag/gCN/EE)纳米复合材料。然后,对溶胀比进行了优化,并根据最佳配方制备了伤口敷料。评估了伤口敷料的释放曲线、生物降解性和机械性能。对 Ag/gCN/EE 的抗菌特性进行了研究,结果表明其对大肠杆菌和金黄色葡萄球菌具有很强的抗菌活性。对 NIH 3T3 成纤维细胞进行了 MTT 检测,BC/Ag/gCN/EE 和 PVA/BC/Ag/gCN/EE 纳米复合材料的存活率分别为 89 ± 2.31 % 和 96 ± 3.28 %,且无毒性。为了评估复合材料对体外伤口愈合和细胞迁移的影响,进行了划痕伤口试验。结果表明,24 小时后,BC/Ag/gCN/EE 和 PVA/BC/Ag/gCN/EE 与对照组相比,划痕面积分别减少了 18.69% 和 23.97%。所制备的复合材料是一种很有前景的伤口敷料,可同时加速伤口愈合和杀灭细菌。
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