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国际材料科学通报

International Journal of Materials Science

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International Journal of Materials Science. 2020; 2: (1) 1; 10.12208/j.ijms.20200001 .

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Principles and design ideas of antiviral activity graphene-based composites
抗病毒活性石墨烯基复合材料的原理与设计思路

作者： 刘健 *, 王朝, 黄政鸿, 甘礼惠

厦门大学能源学院

*通讯作者：刘健,单位：厦门大学能源学院；

厦门大学新型冠状病毒防治应急科研攻关项目

引用本文: 刘健, 王朝, 黄政鸿, 甘礼惠抗病毒活性石墨烯基复合材料的原理与设计思路[J]. 国际材料科学通报, 2020; 2: (1) : 1-5.

Published: 2020/5/21 13:54:51

摘要

本文综述了石墨烯复合材料广谱抗病毒作用机制的研究，包括机械作用、电荷作用、非极性作用、特定基团作用等原理。石墨烯的理化特性与抑制病毒之间的关联原理，很有可能成为开发各类病毒的广谱克星的钥匙。因此，可以依据这些原理，合理选择载体，使氧化石墨烯按照合理方式负载，通过控制材料合成工艺，提升机械作用、电荷作用、非极性作用、特定基团作用等潜在功能，通过考察其带电性质等物化指标，推测其对抗病毒活性的影响，为设计广谱抗病毒石墨烯复合材料提供理论依据。

关键词： 抗病毒；石墨烯；复合材料；设计

Abstract

The research reviews the deepening of the broad-spectrum antiviral mechanism of graphene composites for providing the theoretical basis for the development of safe and effective broad-spectrum antiviral materials, including the principles of mechanical action, charging action, non-polar action, and specific group action. The correlation between the physicochemical properties of graphene and the inhibition of viruses is likely to become the key to the development of broad-spectrum busters of various viruses. Therefore, according to these principles, the carrier can be reasonably selected so that graphene oxide can be loaded in a reasonable manner. By controlling the material synthesis process, the potential functions such as mechanical action, charging action, non-polar action and specific group action can be improved. The physical and chemical indicators such as properties and its antiviral activity are speculated to provide a theoretical basis for designing broad-spectrum antiviral graphene composites.

Key words： Antiviral; Graphene; Composite Material; Design

参考文献 References

[1] PILLAIYAR T, MANICKAN M, NAMASIVAYAM V, et al. An overview of severe acute respiratory syndrome-coronavirus (SARS-CoV) 3CL protease inhibitors: peptidomimetics and small molecule chemotherapy[J].J Med Chem,2016;59 (6595) : 6628.

[2] KARYPIDOUA K, RIBONEBV SR, QUEVEDOB MA. et al. Synthesis, biological evaluation and molecular modeling of a novel series of fused 1,2,3-triazoles as potential anti-coronavirus agents[J].Bioorganic & Medicinal Chemistry Letters 28 (2018) 3472–3476, .

[3] CHEN L, YE S, et al. An aqueous platinum nanotube based fluorescent immuno-assay for porcine reproductive and respiratory syndrome virus detection[J].Talanta,2015; (144) : 324-328.

[4] YE S, LI Z, CHEN F, et al. Porcine epidemic diarrhea virus ORF3 gene prolongs S-phase,facilitates formation of vesicles and promotes the proliferation of attenuated PEDV[J].Virus Genes,2015a;51 (3) : 385-392.

[5] HUANG, X., YIN, Z., WU, S., et al. Graphene-based materials: synthesis,characterization, properties, and applications[J].Small 2011, 7, 1876-1902, .

[6] JANG, H., KIM, Y.K., KWON, H.M., et al. A graphene-based platform for the assay of duplex-DNA unwinding by helicase[J].Angew.Chem. Int. Ed. Engl,2010;49 : 5703-5707.

[7] GURUNATHAN S, HAN JW, ABDAL DA, et al. Oxidative stress-mediated antibacterial activity of graphene oxide and reduced graphene oxide in Pseudomonas aeruginosa[J].Int J Nanomedicine,2012;7 : 5901-5914.

[8] LOH, K.P., BAO, Q., EDA, G., et al. Graphene oxide as a chemically tunable platform for optical applications.Nat. Chem,2010;2 : 1015-1024.

[9] LU C.H., YANG H.H., ZHU C.L., et al. A graphene platform for sensing biomolecules. Angew.Chem.Int. Ed. Engl,2009;48 : 4785-4787.

[10] LUO J., COTE L.J., TUNG V.C., et al. Graphene oxide nanocolloids. J. Am. Chem. Soc.2010;132 : 17667-17669.

[11] LIU S, HU M, et al. Lateral Dimension-Dependent Antibacterial Activity of Graphene Oxide Sheets[J].Langmuir,2012;28 (33) : 12364-12372.

[12] HAGEMEIJER MC, MONASTYSKA I, et al. Membrane rearrangements mediated by coronavirus nonstructural proteins 3 and 4 [J].Virology,2014;458 : 125-135.

[13] LIU S, ZENG TH, et al. Antibacterial activity of graphite, graphite oxide, graphene oxide, and reduced graphene oxide: membrane and oxidative stress[J].ACS nano,2011;5 (9) : 6971-6980.

[14] PERREAULT F, De FARIA AF, et al. Antimicrobial Properties of Graphene Oxide Nanosheets: Why Size Matters[J] .ACS nano,2015b;9 (7) : 7226-7236.

[15] ZOU X, ZHANG L, et al. Mechanisms of the Antimicrobial Activities of Graphene Materials[J].Journal of the American Chemical Society,2016;138 (7) : 2064-2077.

[16] MU, Q., SU, G., LI, L., et al. Size-dependent cell uptake of protein coated graphene oxide nanosheets[J].ACS Appl. Mater. Interfaces,2012;4 : 2259-2266.

[17] 桂芳, 张卓然, 郑丛龙, 等. 消杀型纳米催化剂抗病毒作用的研究[J].中国病毒学,2005;20 (1) : 70-74.

[18] LIANG J, WEI J, et al.. Surfactant-Modified Nanoclay Exhibits an Antiviral Activity with High Potency and Broad Spectrum [J].Journal of Virology,2014;88 (8) : 4218-4228.

[19] YE S, SHAO K, Li Z, et al. Antiviral Activity of Graphene Oxide: How Sharp Edged Structure and Charge Matter[J].ACS Applied Materials & Interfaces,2015;7 (38) : 21571-9.

[20] TU Y, LV M, et al. Destructive extraction of phospholipids from Escherichia coli membranes by graphene nanosheets[J].Nature Nanotechnology,2013;8 (8) : 594-601.

[21] MAZUMDER S, GHOSAL P K, PUJOL C A, et al. Isolation, chemical investigation and antiviral activity of polysaccharides from Gracilaria corticata (Gracilariaceae, Rhodophyta )[J].Internat J Biolog Macro -molec,2002; (9) : 87-95.

[22] MATSUHIRO B, CONTE A F, DAMONTE E B, et al. Structural analysis and antiviral activity of a sulfated gal actan from the red seaweed Schizymenia binderi (Gigartinales, Rhodophyta )[J].Carbohydr Res, (15) : 2392-2402.

[23] 向冬喜, 郑丛龙. 纳米抗菌材料抗病毒作用的研究进展[J].中国微生态学杂志,2009;21 (8) : 760-761.

[24] HU J, LIU J, et al. Surface-Modified Graphene Oxide-Based Cotton Fabric by Ion Implantation for Enhancing Antibacterial Activity[J].ACS Sustainable Chemistry & Engineering. 2019, DOI:10.1021/acssuschemeng.8b06361, .

[25] QIN G, LIU J, et al. Enhanced stability of antimicrobial bamboo fiber by launching ultra fine silver particles in SDS microemulsion system[J] .Textile Research Journal,2017;87 (20) : 2505-2512.

[26] 龙敏南, 秦光辉, 刘健, 甘礼惠. 一种负载纳米银抗菌纤维的制备方法, ZL2015109379569[P].授权公告日: 2017 年7 月4 日, .

Principles and design ideas of antiviral activity graphene-based composites抗病毒活性石墨烯基复合材料的原理与设计思路

摘要

Abstract

参考文献 References

Principles and design ideas of antiviral activity graphene-based composites
抗病毒活性石墨烯基复合材料的原理与设计思路