聚多巴胺辅助的智能细菌响应水凝胶:可切换的抗菌和防污能力,加速伤口愈合。

Zheng Fang, Qingyan He, Yanyu Hu, Xu Chen, Fan Li, Xixi Cai
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引用次数: 0

摘要

导言:耐多药细菌引起的伤口感染和生物膜的形成已构成一系列伤口恶化和危及生命的问题。为了弥补现有灭菌策略的不足,我们亟需一种原位抗细菌粘附、杀灭多重耐药菌并释放死亡细菌的方法:本研究旨在提出一种简便的方法,通过 "抗菌-杀灭-释放 "的方法构建具有可切换抗菌-防污特性的细菌响应水凝胶:方法:智能细菌响应水凝胶是通过两步浸泡策略构建的:在明胶-壳聚糖复合水凝胶表面通过简单的浸泡涂层工艺构建聚多巴胺(pDA)涂层,然后在该pDA涂层上接枝杀菌季铵壳聚糖(QCS)和pH响应PMAA。进一步评估了水凝胶的体外抗菌活性、生物相容性以及在小鼠 MRSA 感染全厚缺损模型中的体内伤口愈合效果:结果:在聚多巴胺涂层的辅助下,pH响应型PMAA和杀菌型QCS成功接枝到明胶-壳聚糖复合水凝胶表面,水凝胶保持了足够的机械性能。在生理条件下,PMAA 水合层赋予了水凝胶抵抗最初细菌附着的能力。一旦细菌定植并使局部环境酸化,膨胀的 PMAA 链就会趋于崩解,然后暴露出杀菌的 QCS,实现按需杀菌。此外,由于 PMAA 在 pH 值升高时具有亲水性,因此死亡的细菌可以被释放出来,水凝胶也会恢复抗性,从而赋予表面可再生能力。体外和体内研究表明,水凝胶具有良好的生物相容性和伤口愈合能力,可抑制感染并进一步促进肉芽组织、血管生成和胶原合成:结论:这一策略为开发和设计智能伤口敷料提供了一种新方法,可用于抗多重耐药菌感染。
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Polydopamine-assisted smart bacteria-responsive hydrogel: Switchable antimicrobial and antifouling capabilities for accelerated wound healing.

Introduction: Wound infections and formation of biofilms caused by multidrug-resistant bacteria have constituted a series of wound deteriorated and life-threatening problems. The in situ resisting bacterial adhesion, killing multidrug-resistance bacteria, and releasing dead bacteria is strongly required to supply a gap of existing sterilization strategies.

Objectives: This study aims to present a facile approach to construct a bacteria-responsive hydrogel with switchable antimicrobial-antifouling properties through a "resisting-killing-releasing" method.

Methods: The smart bacteria-responsive hydrogel was constructed by two-step immersion strategy: a simple immersion-coating process to construct Polydopamine (pDA) coatings on the surface of a gelatin-chitosan composite hydrogel and followed by grafting of bactericidal quaternary ammonium chitosan (QCS) as well as pH-responsive PMAA to this pDA coating. The in vitro antimicrobial activity, biocompatibility and the in vivo wound healing effects in a mouse MRSA-infected full-thickness defect model of the hydrogel were further evaluated.

Results: Assisted by polydopamine coating, the pH-responsive PMAA and bactericidal QCS are successfully grafted onto a gelatin-chitosan composite hydrogel surface and hydrogels maintain the adequate mechanical properties. At physiological conditions, the PMAA hydration layer endows the hydrogel with resistance to initial bacterial attachment. Once bacteria colonize and acidize local environment, the swelling PMAA chains tend to collapse then expose the bactericidal QCS, realizing the on-demand kill bacteria. Moreover, the dead bacteria can be released and the hydrogel will resume the resistance due to hydrophilicity of PMAA at increased pH, endowing the surface renewable ability. In vitro and in vivo studies demonstrate the favorable biocompatibility and wound healing capacity of hydrogels that can inhibit infection and further facilitate granulation tissue, angiogenesis, and collagen synthesis.

Conclusion: This strategy provides a novel methodology for the development and design of smart wound dressing to combat multidrug-resistant bacteria infections.

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