Review of commonly used antibacterial finishing agents for textiles

Abstract

Abstract: Textiles are widely used in many fields, such as clothing, domestic decoration and industrial use. They not only provide a place for the grouth and reproduction of various microorganisms, but also become an important transmission route of some infectious diseases due to their reusable characteristics. In recent years, considering the complex and severe global environmental epidemic and the frequent occurrence of various infectious diseases, the use of antibacterial agents on textiles is an important way to improve their antibacterial and bacteriological properties and cut off or slow down the spread of pathogens. Therefore, the functional characteristics and development trend of various antibacterial agents commonly used in textiles have attracted much attention.
This paper firstly introduces the inorganic, organic and natural antibacterial agents which are widely used in textiles. And the types, characteristics, mechanism of action and antibacterial effect of these compounds are described respectively. Inorganic antibacterial agents are the most widely used antibacterial agents. Nano silver and nano gold as typical antibacterial agents of metal nanoparticles, have high surface energy. They generally destroy the cell structure of bacteria or affect their metabolism by acting with the cell membrane of bacteria. Although they have good antibacterial effects, they are easy to agglomerate and leach from the textile. The antibacterial effect of metal oxides, such as titanium dioxide, zinc oxide and magnesium oxide, is next only to that of metal nanoparticles. There are three main antibacterial mechanisms, such as active oxygen generation through photocatalysis, metal ion action and cell mechanical damage. Carbon nanomaterials have also been studied in the field of antibacterial. It is believed that graphene, carbon nanotubes and graphene oxide can cause physical damage to bacterial cell membrane or cell distortion through contact and interaction with bacteria by their physical structure and excellent mechanical strength, and thus producing antibacterial effects. Organic antibacterial agent is the earliest applied antibacterial agent . They are much easier to prepare and possess a broad spectrum of antibacterial properties, mainly including quaternary ammonium salts, halide amines, triclosan and so on. They kill the bacteria mainly through the chemical bond force, such as electrostatic attraction, van der Waals force, hydrogen bond and so on. Halide amines are considered to be the most effective organic antibacterial agents, which can be cyclically sterilized by artificial chlorination. Although organic antimicrobials have broad-spectrum antibacterial properties, they may be toxic to the environment and human cells. Natural antibacterial agents such as curcumin, chitosan, plant polysaccharides,possess biocompatibility and biodegradability. And they have been paid more and more attention in the antibacterial finishing of textiles, one of the most familiar is chitosan. The amino group on chitosan makes it carry a positive charge, which can be combined with the electrostatic interaction between the bacterial cell membrane and change the permeability of the cell membrane, resulting in cytoplasmic outflow and cell death. But at present, the overall efficiency of natural antibacterial agents is not effectively enough, and the range of use is relatively not extensive. In this paper, two methods of antibacterial finishing of textiles are summarized. One is to prepare antibacterial fiber by directly adding antibacterial agent to spinning liquid seed in the spinning process. The second is the functional finishing method using antibacterial agent on the fabric surface; At last, the paper summarizes three methods of testing textile properties, such as bacteriostatic zone method, absorption method and oscillation method.
At present, problems such as low antibacterial efficiency, poor antibacterial spectrum and insufficient durability need to be solved by antimicrobial agents in textile finishing. At the same time, the problem of poor sensitivity after finishing by antibacterial agents can not be ignored. With the upgrading of use demand and the enhancement of safety and environmental protection awareness, the construction of durable and effective antibacterial coating on textile surface, and study of antibacterial agent type, structure and textile compound antibacterial effect, interface performance and wear evaluation, have become important development directions of antibacterial textile research in the future.

Key words: textile, antibacterial finishing agents, antibacterial mechanism, antibacterial finishing method, antibacterial test

摘要： 近年来，由于新型冠状病毒、甲流等多种传染病频发，抑制和切断病菌的传播成为人们密切关注的焦点。纺织品在使用过程中能够为病菌的生长和繁殖提供有利环境，对人类健康产生极大的影响。提升纺织品的抗菌性能是切断或减缓病菌传播的重要手段，因此抗菌纺织品的研究和应用得到了广泛关注。对纺织品进行抗菌整理是开发抗菌纺织品的常用方法，本文总结了纺织品抗菌整理常用的无机抗菌剂、有机抗菌剂及天然抗菌剂等三类抗菌剂的抗菌作用机理、优缺点以及应用，并对每种抗菌材料的抗菌效果进行了评价。也介绍了纺织品抗菌整理常用的原纤维法和后整理法等两种方法，并总结了纺织品抗菌评价的主要测试手段。最后，本文对纺织品上抗菌整理剂的发展趋势进行展望。

关键词: 纺织品, 抗菌整理剂, 抗菌机理, 抗菌整理, 抗菌测试

CLC Number:

TS101.8

LU Jiayu, CAI Guoqiang, GAO Zongchun, SONG Jiangxiao, ZHANG Yan, QI dongming, . Review of commonly used antibacterial finishing agents for textiles[J]. Advanced Textile Technology, 2023, 31(3): 251-262.

陆嘉渔, 蔡国强, 高宗春, 宋江晓, 张艳, 戚栋明. 纺织品常用的抗菌整理剂的应用综述[J]. 现代纺织技术, 2023, 31(3): 251-262.

References

[1] FERNANDO S, GUNASEKARA T, HOLTON J. Antimicrobial Nanoparticles: applications and mechanisms of action[J]. Sri Lankan Journal of Infectious Diseases, 2018, 8(1): 2.
[2] SEONG M, LEE D G. Silver nanoparticles against Salmonella enterica serotype typhimurium: Role of inner membrane dysfunction[J]. Current Microbiology, 2017, 74(6): 661-670.
[3] 王荣国, 王进美. 纺织品抗菌剂及其整理方法[J]. 合成纤维, 2021, 50(8): 24-26, 37.
WANG Rongguo, WANG Jinmei. Antimicrobial finishing of textile and its finishing method[J]. Synthetic Fiber in China, 2021, 50(8): 24-26, 37.
[4] KHAN I, SAEED K, KHAN I. Nanoparticles: Properties, applications and toxicities[J]. Arabian Journal of Chemistry, 2019, 12(7): 908-931.
[5] IVASK A, ELBADAWY A, KAWEETEERAWAT C, et al. Toxicity mechanisms in Escherichia coli vary for silver nanoparticles and differ from ionic silver[J]. ACS Nano, 2014, 8(1): 374-386.
[6] EREMENKO A M, PETRIK I S, SMIRNOVA N P, et al. Antibacterial and antimycotic activity of cotton fabrics, impregnated with silver and binary silver/copper nanoparticles[J]. Nanoscale Research Letters, 2016, 11(1): 28.
[7] QUINTEROS M A, CANO ARISTIZÁBAL V, DALMASSO P R, et al. Oxidative stress generation of silver nanoparticles in three bacterial Genera and its relationship with the antimicrobial activity[J]. Toxicology in Vitro, 2016, 36: 216-223.
[8] KAWABATA N, Nishiguchi M. Antibacterial activity of soluble pyridinium-type polymers[J]. Applied and Environmental Microbiology, 1988, 54(10): 2532-2535.
[9] AGNIHOTRI S, MUKHERJI S. Immobilized silver nanoparticles enhance contact killing and show highest efficacy: elucidation of the mechanism of bactericidal action of silver[J]. Nanoscale, 2013, 5(16):7328-7340.
[10] LI P P, WU H X, DONG A. Ag/AgX nanostructures serving as antibacterial agents: Achievements and challenges[J]. Rare Metals, 2022, 41(2): 519-539.
[11] ZHANG G Y, LIU Y, GAO X L, et al. Synthesis of silver nanoparticles and antibacterial property of silk fabrics treated by silver nanoparticles[J]. Nanoscale Research Letters, 2014, 9(1): 216.
[12] ZHANG F, WU X L, CHEN Y Y, et al. Application of silver nanoparticles to cotton fabric as an antibacterial textile finish[J]. Fibers and Polymers, 2009, 10(4): 496-501.
[13] ZHANG Z Y, LV X D, CHEN Q D, et al. Complex coloration and antibacterial functionalization of silk fabrics based on noble metal nanoparticles[J]. Journal of Engineered Fibers and Fabrics, 2019, 14: 155892501986694.
[14] CHATTERJEE A K, CHAKRABORTY R, BASU T. Mechanism of antibacterial activity of copper nanoparticles[J]. Nanotechnology, 2014, 25(13): 135101.
[15] JEEVANANDAM J, CHAN Y S, DANQUAH M K. Biosynthesis of metal and metal oxide nanoparticles[J]. ChemBioEng Reviews, 2016, 3(2): 55-67.
[16] RANJAN S, RAMALINGAM C. Titanium dioxide nanoparticles induce bacterial membrane rupture by reactive oxygen species generation[J]. Environmental Chemistry Letters, 2016, 14(4): 487-494.
[17] RAEISI M, KAZEROUNI Y, MOHAMMADI A, et al. Superhydrophobic cotton fabrics coated by chitosan and titanium dioxide nanoparticles with enhanced antibacterial and UV-protecting properties[J]. International Journal of Biological Macromolecules, 2021, 171: 158-165.
[18] INGUANTA R, GARLISI C, SPANÒ T, et al. Growth and photoelectrochemical behaviour of electrodeposited ZnO thin films for solar cells[J]. Journal of Applied Electrochemistry, 2013, 43(2): 199-208.
[19] SEIL J T, WEBSTER T J. Antimicrobial applications of nanotechnology: Methods and literature[J]. International Journal of Nanomedicine, 2012, 7: 2767-2781.
[20] ADAMS L K, LYON D Y, ALVAREZ P J J. Comparative eco-toxicity of nanoscale TiO2, SiO2, and ZnO water suspensions[J]. Water Research, 2006, 40(19): 3527-3532.
[21] LIPOVSKY A, NITZAN Y, GEDANKEN A, et al. Antifungal activity of ZnO nanoparticles: The role of ROS mediated cell injury[J]. Nanotechnology, 2011, 22(10): 105101.
[22]Ghasemi N, Seyfi J, Asadollahzadeh M J. Imparting superhydrophobic and antibacterial properties onto the cotton fabrics: synergistic effect of zinc oxide nanoparticles and octadecanethiol[J]. Cellulose, 2018,25(7): 4211-4222.
[23] CAI L, CHEN J N, LIU Z W, et al. Magnesium oxide nanoparticles: Effective agricultural antibacterial agent against ralstonia solanacearum[J]. Frontiers in Microbiology,2018, 9: 790.
[24] NGUYEN T N, BUI V K H, LEE Y C. Development of antimicrobial MgO-CuO/activated carbon fiber[J]. Journal of Nanoscience and Nanotechnology, 2021, 21(7): 4055-4059.
[25] JANG H, RYOO S R, KOSTARELOS K, et al. The effective nuclear delivery of doxorubicin from dextran-coated gold nanoparticles larger than nuclear pores[J]. Biomaterials, 2013, 34(13): 3503-3510.
[26] AL-JUMAILI A, ALANCHERRY S, BAZAKA K, et al. The electrical properties of plasma-deposited thin films derived from pelargonium graveolens[J]. Electronics, 2017, 6(4): 86.
[27] ALLEN M J, TUNG V C, KANER R B. Honeycomb carbon: A review of graphene[J]. Chemical Reviews, 2010, 110(1): 132-145.
[28] PINTO A M, GONÇALVES I C, MAGALHÃES F D. Graphene-based materials biocompatibility: A review[J]. Colloids and Surfaces B: Biointerfaces, 2013, 111: 188-202.
[29] TU Y S, LV M, XIU P, et al. Destructive extraction of phospholipids from Escherichia coli membranes by graphene nanosheets [J]. Nature Nanotechnology, 2013, 8(8): 594-601.
[30] CHEN D, WANG G, LI J H, et al. Graphene film synthesis on SiGe semiconductor substrate for field-effect transistor[J]. Materials Letters, 2014, 135: 222-225.
[31] GHOSH S, GANGULY S, DAS P, et al. Fabrication of reduced graphene oxide/silver nanoparticles decorated conductive cotton fabric for high performing electromagnetic interference shielding and antibacterial application[J]. Fibers and Polymers, 2019, 20(6): 1161-1171.
[32] ZHAO J, WANG Z Y, WHITE J C, et al. Graphene in the aquatic environment: adsorption, dispersion, toxicity and transformation[J]. Environmental Science & Technology, 2014, 48(17): 9995-10009.
[33] PIEPER H, HALBIG C E, KOVBASYUK L, et al. Oxo-functionalized graphene as a cell membrane carrier of nucleic acid probes controlled by aging[J]. Chemistry (Weinheim an Der Bergstrasse, Germany), 2016, 22(43): 15389-15395.
[34] ROMERO-VARGAS CASTRILLÓN S, PERREAULT F, DE FARIA A F, et al. Interaction of graphene oxide with bacterial cell membranes: Insights from force spectroscopy[J]. Environmental Science & Technology Letters, 2015, 2(4): 112-117.
[35] AKHAVAN O, GHADERI E. Toxicity of graphene and graphene oxide nanowalls against bacteria[J]. ACS Nano, 2010, 4(10): 5731-5736.
[36] ZHAO L H, ZHANG S Y, WANG Y W, et al. Antibacterial graphene oxide/chitosan composite compression garment fabric[J]. Fibers and Polymers, 2022, 23(7): 1834-1845.
[37] GURUNATHAN S, HAN J W, DAYEM A A, et al. Oxidative stress-mediated antibacterial activity of graphene oxide and reduced graphene oxide in Pseudomonas aeruginosa[J]. International Journal of Nanomedicine
[38] PAN N Y, WEI Y M, ZUO M D, et al. Antibacterial poly (ε-caprolactone) fibrous membranes filled with reduced graphene oxide-silver[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2020, 603: 125186.
[39] 顾宁, 李洋. 纳米颗粒对细胞膜的作用[J]. 生物物理学报, 2010, 26(8): 623-637.
GU Ning, LI Yang. Interaction of nanoparticles on cell membranes[J].Acta biophysica sinica,2010,26(08):623-637.
[40] KANG S, PINAULT M, PFEFFERLE L D, et al. Single-walled carbon nanotubes exhibit strong antimicrobial activity[J]. Langmuir, 2007, 23(17): 8670-8673.
[41] SHI H C, LIU H Y, LUAN S F, et al. Effect of polyethylene glycol on the antibacterial properties of polyurethane/carbon nanotube electrospun nanofibers[J]. RSC Advances,2016,6(23): 19238-19244.
[42] JATOI A W, OGASAWARA H, KIM I S, et al. Cellulose acetate/multi-wall carbon nanotube/Ag nanofiber composite for antibacterial applications[J]. Materials Science and Engineering: C, 2020, 110: 110679.
[43] 李俊, 张勇杰, 李运玲, 等. 季铵盐杀菌剂的现状与发展趋势[J]. 日用化学品科学, 2015, 38(9): 32-35,39.
LI Jun, ZHANG Yongjie, LI Yunling, et al. Current state and development of quaternary ammonium salt bactericides.
[44] 周旋峰, 石荣莹. 阳离子杀菌剂的现状及其发展趋势[J]. 中国洗涤用品工业, 2020(S1): 187-193.
ZHOU Xuanfeng, SHI Rongyin. Current state and development trend of cationic bactericides[J]. China Cleaning Industry, 2020(S1): 187-193.
[45] SIMONCIC B, TOMSIC B. Structures of novel antimicrobial agents for textiles: A review[J]. Textile Research Journal, 2010, 80(16): 1721-1737.
[46] GAO D G, LI Y J, LYU B, et al. Silicone quaternary ammonium salt based nanocomposite: a long-acting antibacterial cotton fabric finishing agent with good softness and air permeability[J]. Cellulose, 2020, 27(2)：1055-1069.
[47] ZHU C Y, CHANG D, WANG X, et al. Novel antibacterial fibers of amphiphilic N-halamine polymer prepared by electrospinning[J]. Polymers for Advanced Technologies, 30(6):1386-1393.
[48] ZHANG C, CUI F, ZENG G M, et al. Quaternary ammonium compounds (QACs): A review on occurrence, fate and toxicity in the environment[J]. Science of the Total Environment, 2015, 518/519: 352-362.
[49] DONG A, WANG Y J, GAO Y Y, et al. Chemical insights into antibacterial N-halamines[J]. Chemical Reviews, 2017, 117(6): 4806-4862.
[50] CHEN X Q, LIU Z L, CAO W W, et al. Preparation, characterization, and antibacterial activities of quaternarized N-halamine-grafted cellulose fibers[J]. Journal of Applied Polymer Science, 2015, 132(43)：42702.
[51] ORHAN M, KUT D, GUNESOGLU C. Use of triclosan as antibacterial agent in textiles[J]. Indian Journal of Fibre & Textile Research, 2007, 32(1): 114-118.
[52] ORHAN M. Triclosan applications for biocidal functionalization of polyester and cotton surfaces[J]. Journal of Engineered Fibers and Fabrics, 2020, 15: 155892502094010.
[53] DINWIDDIE M T, TERRY P D, CHEN J G. Recent evidence regarding triclosan and cancer risk[J]. International Journal of Environmental Research and Public Health, 2014, 11(2): 2209-2217.
[54] 刘小芳, 吴云明, 李建德, 等. 苯扎氯铵溶液一次性用于感染腹腔冲洗的可行性研究[J]. 中国临床药理学与治疗学, 2013, 18(8): 885-890.
LIU Xiaofang, WU Yunmin, LI Jiande, et al. Benzalkonium chloride solution feasibility research on infected abdomen for disposable peritoneal irrigation[J]. Chinese Journal of Clinical Pharmacology and Therapeutics, 2013,18(8):885-890.
[55] HAN H, ZHU J, WU D Q, et al. Inherent guanidine nanogels with durable antibacterial and bacterially antiadhesive properties[J]. Advanced Functional Materials, 2019, 29(12): 1806594.
[56] SHENTU X Y, GUAN Y, WANG L L, et al. Preparation of antibacterial down fibers by chemical grafting using novel guanidine salt oligomer[J]. Polymers for Advanced Technologies, 2021, 32(10): 4082-4093.
[57] LIU X L, LIU H, QU X, et al. Electrical signals triggered controllable formation of calcium-alginate film for wound treatment[J]. Journal of Materials Science Materials in Medicine, 2017, 28(10): 146.
[58] SU L, YU Y, ZHAO Y S, et al. Strong antibacterial polydopamine coatings prepared by a shaking-assisted method[J]. Scientific Reports, 2016, 6: 24420.
[59] LI Z M, SHAN X T, CHEN Z D, et al. Applications of surface modification technologies in nanomedicine for deep tumor penetration[J]. Advanced Science, 2020, 8(1): 2002589.
[60] LI Y Z, WANG B J, SUI X F, et al. Durable flame retardant and antibacterial finishing on cotton fabrics with cyclotriphosphazene/polydopamine/silver nanoparticles hybrid coatings[J]. Applied Surface Science, 2018, 435: 1337-1343.
[61] SHAHIDI F, ARACHCHI J K V, JEON Y J. Food applications of chitin and chitosans[J]. Trends in Food Science & Technology, 1999, 10(2): 37-51.
[62] SUDARSHAN N R, HOOVER D G, KNORR D. Antibacterial action of chitosan [J]. Food Biotechnology, 1992, 6(3): 257-272.
[63] RAAFAT D, VON BARGEN K, HAAS A, et al. Insights into the mode of action of chitosan as an antibacterial compound[J]. Applied and Environmental Microbiology, 2008, 74(12): 3764-3773.
[64] TANG R L, YU Z M, ZHANG Y, et al. Synthesis, characterization, and properties of antibacterial dye based on chitosan[J]. Cellulose, 2016, 23(3): 1741-1749.
[65] YU J, PANG Z Y, ZHANG J, et al. Conductivity and antibacterial properties of wool fabrics finished by polyaniline/chitosan[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2018, 548: 117-124.
[66] GOY R C, MORAIS S T B, ASSIS O B G. Evaluation of the antimicrobial activity of chitosan and its quaternized derivative on E. coli and S. aureus growth[J]. Revista Brasileira De Farmacognosia, 2016, 26(1): 122-127.
[67] RESHMA A, PRIYADARISINI V B, AMUTHA K. Sustainable antimicrobial finishing of fabrics using natural bioactive agents-a review[J]. International Journal of Life Science and Pharma Research, 2018, 8(4): 10-20.
[68] LIU M J, LU Y L, GAO P, et al. Effect of curcumin on laying performance, egg quality, endocrine hormones, and immune activity in heat-stressed hens[J]. Poultry Science, 2020, 99(4): 2196-2202.
[69] MAHMUD M M, ZAMAN S, PERVEEN A, et al. Controlled release of curcumin from electrospun fiber mats with antibacterial activity[J]. Journal of Drug Delivery Science and Technology, 2020, 55: 101386.
[70] WANG Q X, LIU S L, LU W J, et al. Fabrication of Curcumin@Ag loaded core/shell nanofiber membrane and its synergistic antibacterial properties[J]. Frontiers in Chemistry, 2022, 10 : 870666.
[71] BLOCK E. The chemistry of garlic and Onions[J]. Scientific American, 1985, 252(3): 114-119.
[72] CAVALLITO C J, BAILEY J H. Allicin, the antibacterial principle of allium sativum. I. isolation, physical properties and antibacterial action[J]. Journal of the American Chemical Society, 1944, 66(11): 1950-1951.
[73] OMAR S H, AL-WABEL N A. Organosulfur compounds and possible mechanism of garlic in cancer[J]. Saudi Pharmaceutical Journal, 2010, 18(1): 51-58.
[74] 熊晓辉, 李星, 孙芸, 等. 大蒜中硫代亚磺酸酯提取工艺及其稳定性研究[J]. 食品与发酵工业, 2013, 39(1): 194-198.
XIONG Xiaohui, LI Xing, SUN Yun, et al. Stability of thiosulfinates and its extraction technology in garlic[J]. Food and Fermentation Industries, 2013, 39(1): 194-198.
[75] ANKRI S, MIRELMAN D. Antimicrobial properties of allicin from garlic[J]. Microbes and infection, 1999, 1(2): 125-129.
[76] CUI Y, ZHAO Y Y, TIAN Y, et al. The molecular mechanism of action of bactericidal gold nanoparticles on Escherichia coli[J]. Biomaterials, 2012, 33(7): 2327-2333.
[77] EDIKRESNHA D, SUCIATI T, MUNIR M M, et al. Polyvinylpyrrolidone/cellulose acetate electrospun composite nanofibres loaded by glycerine and garlic extract with in vitro antibacterial activity and release behaviour test[J]. RSC Advances, 2019, 9(45): 26351-26363.
[78] HUSSAIN N, ULLAH S, SARWAR M N, et al. Fabrication and characterization of novel antibacterial ultrafine nylon-6 nanofibers impregnated by garlic sour[J]. Fibers and Polymers, 2020, 21(12): 2780-2787.
[79] ZHOU Y, CHEN X X, CHEN T T, et al. A review of the antibacterial activity and mechanisms of plant polysaccharides[J]. Trends in Food Science & Technology, 2022, 123: 264-280.
[80] ALKAHTANI J, SOLIMAN ELSHIKH M, ALMAARY K S, et al. Anti-bacterial, anti-scavenging and cytotoxic activity of garden cress polysaccharides [J]. Saudi Journal of Biological Sciences,2020, 27(11): 2929-2935.
[81] DE ANDRADE E W V, DUPONT S, BENEY L, et al. Osmoporation is a versatile technique to encapsulate fisetin using the probiotic bacteria Lactobacillus acidophilus[J]. Applied Microbiology and Biotechnology, 2022, 106(3): 1031-1044.
[82] MENG Q R, LI Y H, XIAO T C, et al. Antioxidant and antibacterial activities of polysaccharides isolated and purified from Diaphragma juglandis fructus[J]. International Journal of Biological Macromolecules, 2017, 105: 431-437.
[83] LIN L, ZHU Y L, LI C Z, et al. Antibacterial activity of PEO nanofibers incorporating polysaccharide from dandelion and its derivative[J]. Carbohydrate Polymers, 2018, 198: 225-232.
[84] LIANG X P, ZHU M J, LI H F, et al. Hydrophilic, breathable, and washable graphene decorated textile assisted by silk sericin for integrated multimodal smart wearables[J]. Advanced Functional Materials, 2022, 32(42): 2200162.
[85] 张卓成. 抗菌整理剂的设计合成及其在纺织品中的应用[D].深圳：深圳大学, 2020.
ZHANG Zhuochen. Design and Synthesis of Antibacterial Finishing Agent and Its Application in Textile [D].Shenzhen：Shenzhen University, 2020.
[86] 梁卡, 邓浩, 田艳红, 等. 纺织品抗菌性能测试方法[J]. 国际纺织导报, 2015, 43(9): 54-56,58.
LIANG Ka, DENG Hao, TIAN Yanhong, et al. Testing methods for antibacterial activity of textiles[J]. Melliand China. 2015, 43(09): 54-56,58.