Anchoring silver nanoparticles on nanofibers by thermal bonding to construct functional surface.

IF 1.6 4区医学 Q4 BIOPHYSICS Biointerphases Pub Date : 2022-11-14 DOI:10.1116/6.0002206

Bingjie Xu, Langfei Yang, Wei Pan, Ying Li, Zili Wang, Guoqiang Cai, Jindan Wu, Dongming Qi

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Abstract

Generally, the anchoring of inorganic nanoparticles onto the surface of fibers faces the problem of poor stability, which limits the wide application of nanoparticle functionalized fibers. Herein, nanofibers with shell-core structures were constructed by coaxial electrospinning of two polymers with different melting points (T_m). Polyglycolic acid (PGA, T_m = 225 °C) was employed as the core layer, while polycaprolactone (PCL, T_m = 60 °C) was used as the shell layer. Silver nanoparticles (AgNPs) were electrosprayed on the nanofibers and the shell layer (PCL) was heated and melted to bond the AgNPs, thus realizing a stable AgNP-composited nanofiber for the construction of antibacterial functional surface. By regulating the shell-core flow ratio and the condition for heat treatment, the appropriate thickness of the shell layer was obtained with a flow ratio of 3:1 (PCL:PGA). The optimal composite structure was constructed when the thermal bonding was taken under 80 °C for 5 min. Furthermore, it was found that the composite nanofibers prepared by thermal bonding had better hydrophilicity, mechanical property, and AgNPs bonding stability, and their antibacterial rate against Staphylococcus aureus (S. aureus) reached over 97%. Overall, a facile and universal method for the preparation of nanoparticle-anchored nanofibers was established in this study. The robust nanoparticle-composited nanofibers are promising for applications in optoelectronic devices, electrode materials, and so on.

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用热键法将银纳米粒子固定在纳米纤维上，构建功能表面。

无机纳米粒子在纤维表面的锚定通常面临稳定性差的问题，这限制了纳米粒子功能化纤维的广泛应用。本文以两种不同熔点(Tm)的聚合物为材料，采用同轴静电纺丝的方法制备了具有壳核结构的纳米纤维。聚乙醇酸(PGA, Tm = 225℃)为核心层，聚己内酯(PCL, Tm = 60℃)为壳层。将银纳米粒子(AgNPs)电喷涂在纳米纤维上，加热熔化壳层(PCL)粘合AgNPs，从而实现稳定的AgNPs复合纳米纤维，用于构建抗菌功能表面。通过调节壳芯流量比和热处理条件，获得了流量比为3:1 (PCL:PGA)的合适壳层厚度。在80℃下热键合5 min时，构建了最佳的复合结构。进一步研究发现，热键合制备的复合纳米纤维具有更好的亲水性、力学性能和AgNPs键合稳定性，对金黄色葡萄球菌(S. aureus)的抑菌率达到97%以上。总之，本研究建立了一种简便、通用的纳米颗粒锚定纳米纤维制备方法。坚固耐用的纳米颗粒复合纳米纤维在光电器件、电极材料等方面具有广阔的应用前景。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Biointerphases 生物-材料科学：生物材料

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期刊介绍： Biointerphases emphasizes quantitative characterization of biomaterials and biological interfaces. As an interdisciplinary journal, a strong foundation of chemistry, physics, biology, engineering, theory, and/or modelling is incorporated into originated articles, reviews, and opinionated essays. In addition to regular submissions, the journal regularly features In Focus sections, targeted on specific topics and edited by experts in the field. Biointerphases is an international journal with excellence in scientific peer-review. Biointerphases is indexed in PubMed and the Science Citation Index (Clarivate Analytics). Accepted papers appear online immediately after proof processing and are uploaded to key citation sources daily. The journal is based on a mixed subscription and open-access model: Typically, authors can publish without any page charges but if the authors wish to publish open access, they can do so for a modest fee. Topics include: bio-surface modification nano-bio interface protein-surface interactions cell-surface interactions in vivo and in vitro systems biofilms / biofouling biosensors / biodiagnostics bio on a chip coatings interface spectroscopy biotribology / biorheology molecular recognition ambient diagnostic methods interface modelling adhesion phenomena.