渗出液
伤口愈合
蒸腾作用
薄壁组织
光热治疗
生物医学工程
材料科学
化学
园艺
纳米技术
植物
外科
医学
生物化学
生物
光合作用
作者
Ying Li,Yi Zhang,Yixin Wang,Kun Yu,Enling Hu,Fei Lu,Songmin Shang,Ruiqi Xie,Guangqian Lan
标识
DOI:10.1016/j.cej.2021.131964
摘要
Exudate regulation, which helps maintain an optimal moisture content in the wound bed and protects the surrounding skin from maceration, is a prerequisite for wound healing. In this study, inspired by the natural hierarchical structure of sugarcane, in which vascular bundles are responsible for transporting water and parenchyma cells are responsible for storing sucrose, we fabricated a continuously self-draining sugarcane stem-based dressing to remove exudates from overhydrated wounds. Sugarcane cellulosic frameworks (SCF), obtained via alkali and de-sugaring treatments of natural sugarcane substrates (SS), were coated with gold nanorods (AuNRs) to facilitate photothermal responsiveness under near-infrared (NIR) irradiation. By mimicking plant transpiration and incorporating a stimulus-responsive feature, natural SS were transformed into exudate-managing dressing materials for accelerated wound healing. As the obtained sugarcane frameworks ([email protected]) contained abundant vascular bundles and exhibited photothermal responsiveness, it was able to self-drain exudates continuously with a high evaporation efficiency (95%). In order to endow the dressing with antibacterial properties, Ag nanoparticles (AgNPs) was incorporated with [email protected] to form [email protected]@SCF. The healing process in a wound model was more rapid with [email protected]@SCF with NIR irradiation than with a commercial dressing. Moreover, as the parenchyma cells in [email protected]@SCF formed closed chambers after de-sugaring, [email protected]@SCF facilitated effective thermal insulation (thermal conductivity of 0.04 W m−1k−1) for protecting the underlying wound, even when the temperature of the top surface was high (53 °C). As this hierarchical structure is naturally existent in other Poaceae plants, which are sustainable green resources, our findings may provide a new strategy for the fabrication of versatile and efficient self-draining dressings for exudate management and wound healing.
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