<i>N</i>-Halamine-Containing Electrospun Fibers Kill Bacteria via a Contact/Release Co-Determined Antibacterial Pathway

Bai, Rong; Zhang, Qing; Li, Lanlan; Li, Ping; Wang, Yanjie; Simalou, Oudjaniyobi; Zhang, Yanling; Gao, Ge; Dong, Alideertu

doi:10.1021/acsami.6b08431

Cited by 85 publications

(48 citation statements)

References 48 publications

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“…The research of inhibition zone has provided some information for the bactericidal mechanism of N ‐halamines. The research of inhibition zone has provided some information for the bactericidal mechanism of N ‐halamines . It shows that the bactericidal effect can be achieved by releasing oxidized chlorine.…”

Section: Resultsmentioning

confidence: 99%

“…Goddard's group has synthesized an efficient antibacterial coating by compounding N ‐halamines into the coating . Liang and coworkers have synthesized antibacterial composites with graphene oxide and titanium dioxide, and Dong and coworkers have prepared the composites of N ‐halamine polymer by electrospinning . At present, most of the monomers used to synthesize N ‐halamine polymers are mainly methyl methacrylate compounds, and most of the polymers are hydrophobic .…”

Section: Introductionmentioning

confidence: 99%

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Novel hydrophilic N‐halamine polymer with enhanced antibacterial activity synthesized by inverse emulsion polymerization

Xiao

Hao

Chang

et al. 2018

J of Applied Polymer Sci

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N-halamine-based antibacterial agents have high efficiency and rechargeable antibacterial properties. However, their applications are limited due to their complex synthetic process and fuzzy antibacterial mechanism. In this study, a novel N-halamine antibacterial polymer was synthesized by inverse emulsion polymerization and characterized by Fourier transform infrared, nuclear magnetic resonance, scanning electron microscopy, thermogravimetric analysis, and X-ray photoelectron spectroscopy. Due to the difficulty of purification, most of the subjects studied previously were hydrophobic polymers, while little research on hydrophilic polymers. In this experiment, this difficulty was overcome by controlling the dosage of sodium hypochlorite and methods of dialysis. Because of the complex cell structure of Gram-negative bacteria, it is difficult for N-halamines to release the oxidizing chlorine into the cell. However, the hydrophilic N-halamines can solve this problem, which showed a stronger antibacterial effect on Gram-negative Escherichia coli synthesized in this study. In addition, the particle size and hydrophilic property of the polymer were changed by changing the amount of initiator, and the differences in their antibacterial properties were studied.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Novel hydrophilic N‐halamine polymer with enhanced antibacterial activity synthesized by inverse emulsion polymerization

Xiao

Hao

Chang

et al. 2018

J of Applied Polymer Sci

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“…In response to this challenge, various antibacterial agents have been developed for application in protective masks, such as silver nanoparticles, 10,11 chitosan, 12 silk, 13 soy protein isolates, 14 N-halamines, 15 etc., among which N-halamines exhibit absolute advantages over others owing to their high biocidal activity against a broad spectrum of bacteria, long-term structural stability, and rechargeable antibacterial properties. 16,17 Generally, rechargeable N-halamines can be formed by the substitution of hydrogen on the amide nitrogen, generating halogen atoms with a strong oxidative state, which can kill bacteria by damaging their structures. 16,18 By virtue of the desirable properties of abundant amide groups, easy accessibility, and good processibility, polyamides (PAs) have great potential for the preparation of N-halamine structured biocidal materials.…”

Section: Introductionmentioning

confidence: 99%

Rechargeable polyamide-basedN-halamine nanofibrous membranes for renewable, high-efficiency, and antibacterial respirators

Wang

et al. 2019

Nanoscale Adv.

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Emerging infectious diseases (EIDs) have been acknowledged as a major public health concern worldwide. Unfortunately, most protective respirators used to prevent EID transmission suffer from the disadvantage of lacking antimicrobial activity, leading to an increased risk of cross-contamination and post-infection. Herein, we report a novel and facile strategy to fabricate rechargeable and biocidal air filtration materials by creating advanced N-halamine structures based on electrospun polyamide (PA) nanofibers. Our approach can endow the resultant nanofibrous membranes with powerful biocidal activity (6 log CFU reduction against E. coli), an ultrahigh fine particle capture efficiency of 99.999% (N100 level for masks), and can allow the antibacterial efficacy and air filtration performance to be renewed in a one-step chlorination process, which has never been reported before. More importantly, for the first time, we revealed the synergistic effect involving the intrinsic structure of polymers and the assembling structure of nanofibers on the chlorination capacity. The successful fabrication of such a fascinating membrane can provide new insights into the development of nanofibrous materials in a multifunctional, durable, and renewable form. † Electronic supplementary information (ESI) available: Experimental setup for the evaluation of air ltration performance; a self-designed test platform for recycling ltration performance; viscosity and conductivity of PA-6, PA-66, and PA-610 solutions; morphologies of PA-6, PA-66, and PA-610 nanobrous membranes aer chlorination; the mechanical properties of PA-6, PA-66, and PA-610 nanobrous membranes; the morphology of PA-6 nanobrous membranes aer 5 repeated quenching/chlorination cycles; clean air delivery rate of charged PA-6 nanobrous membranes during recycling tests; the structural parameters of PA-6 nanobrous membranes before and aer chlorination. See

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“…Electrospinning technique provided us a successful and efficient physical method to synthesize various composite fibers in antibacterial fields; some of the research groups have begun to utilize nanotechnology in the synthesis of N ‐halamine‐based nanoparticles in antibacterial applications . Nanosized N ‐halamines, resulting from effective polymeric methods and the combination of advanced nanotechnology, have attracted increasing attention in the antibacterial field due to their enhanced antibacterial efficiency …”

Section: Introductionmentioning

confidence: 99%

“…26 Nanosized N-halamines, resulting from effective polymeric methods and the combination of advanced nanotechnology, have attracted increasing attention in the antibacterial field due to their enhanced antibacterial efficiency. 27,28 As hydrophilic and hydrophobic components in polymers played crucial roles, an important understanding to the optimal hydrophobic/hydrophilic balance, hydrophobic content, and facial amphiphilicity was strongly correlated with antimicrobial activity and selectivity of polymers. 29 Water dispersible/soluble polymers are advantageous in terms of industrial applications and environmental concerns.…”

Section: Introductionmentioning

confidence: 99%

Novel antibacterial fibers of amphiphilic N‐halamine polymer prepared by electrospinning

Zhu

Chang

Wang

et al. 2019

Polymers for Advanced Techs

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As a significant role in subcategory of halogen antibacterial field, amphiphilic N‐halamine polymers show a promise as potential antimicrobials having a broad spectrum of microorganisms, long‐term stability, and renewal of their antibacterial properties. By controlling the process parameters, electrospinning has been well recognized as a versatile and effective method being capable of making fibers and could be easily engineered with desired pore size and porosity to enhance the antimicrobial properties. The amphiphilic N‐halamine P (ADMH‐MMA‐HEMA) terpolymer fibers showed efficient antimicrobial properties against both Gram‐positive and Gram‐negative bacteria within brief contact time. The result meant that the polymer fibers of macromolecular architecture with control of structural parameters such as hydrophobicity/hydrophilicity balance achievement improved antimicrobial activities via electrospinning technique. In vitro cytotoxicity study demonstrated that the polymer was biocompatible. As a result, the integration of amphiphilic antibacterial materials and the electrospinning technique provided us a feasible method to fabricate biocompatible antimicrobial products easily with low manufacturing cost and would be applied in many promising application areas.

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N-Halamine-Containing Electrospun Fibers Kill Bacteria via a Contact/Release Co-Determined Antibacterial Pathway

Cited by 85 publications

References 48 publications

Novel hydrophilic N‐halamine polymer with enhanced antibacterial activity synthesized by inverse emulsion polymerization

Novel hydrophilic N‐halamine polymer with enhanced antibacterial activity synthesized by inverse emulsion polymerization

Rechargeable polyamide-basedN-halamine nanofibrous membranes for renewable, high-efficiency, and antibacterial respirators

Novel antibacterial fibers of amphiphilic N‐halamine polymer prepared by electrospinning

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