National & Local Joint Engineering Research Center of Biodiagnosis and Biotherapy, The Second Affiliated Hospital of Xi'an Jiaotong University, Xi'an, 710004, PR China.
School of Chemical Engineering and Technology, Shaanxi Key Laboratory of Energy Chemical Process Intensification, Institute of Polymer Science in Chemical Engineering, Xi'an Jiaotong University, Xi'an, 710049, PR China.
Biomaterials. 2025 Feb;313:122794. doi: 10.1016/j.biomaterials.2024.122794. Epub 2024 Aug 30.
Complex tissue damage accompanying with bacterial infection challenges healthcare systems globally. Conventional tissue engineering scaffolds normally generate secondary implantation trauma, mismatched regeneration and infection risks. Herein, we developed an easily implanted scaffold with multistep shape memory and photothermal-chemodynamic properties to exactly match repair requirements of each part from the tissue defect by adjusting its morphology as needed meanwhile inhibiting bacterial infection on demand. Specifically, a thermal-induced shape memory scaffold was prepared using hydroxyethyl methacrylate and polyethylene glycol diacrylate, which was further combined with the photothermal agent iron tannate (FeTA) to produce NIR light-induced shape memory property. By varying ingredients ratios in each segment, this scaffold could perform a stepwise recovery under different NIR periods. This process facilitated implantation after shape fixing to avoid trauma caused by conventional methods and gradually filled irregular defects under NIR to perform suitable tissue regeneration. Moreover, FeTA also catalyzed Fenton reaction at bacterial infections with abundant HO, which produced excess ROS for chemodynamic antibacterial therapy. As expected, bacteriostatic rate was further enhanced by additional photothermal therapy under NIR. The in vitro and vivo results showed that our scaffold was able to perform high efficacy in both antibiosis, inflammation reduction and wound healing acceleration, indicating a promising candidate for the regeneration of complex tissue damage with bacterial infection.
伴随细菌感染的复杂组织损伤对全球医疗保健系统构成挑战。传统的组织工程支架通常会产生二次植入创伤、再生不匹配和感染风险。在此,我们开发了一种具有多步形状记忆和光热-化学动力学特性的易于植入的支架,通过根据需要调整其形态来精确匹配组织缺陷各部分的修复要求,同时按需抑制细菌感染。具体来说,使用甲基丙烯酸羟乙酯和聚乙二醇二丙烯酸酯制备了热诱导形状记忆支架,然后将其与光热剂单宁酸铁(FeTA)结合,产生近红外光诱导形状记忆性能。通过改变每个部分的成分比例,该支架可以在不同的近红外周期下进行逐步恢复。这个过程在形状固定后方便了植入,避免了传统方法造成的创伤,并在近红外光下逐渐填充不规则缺陷,进行适当的组织再生。此外,FeTA 在细菌感染时还会催化芬顿反应,产生丰富的 HO,用于化学动力学抗菌治疗产生过量的 ROS。不出所料,在近红外光下进行额外的光热治疗进一步提高了抑菌率。体外和体内结果表明,我们的支架在抗菌、减轻炎症和加速伤口愈合方面都具有很高的疗效,这表明它是治疗伴有细菌感染的复杂组织损伤的一种很有前途的候选材料。
