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·2414· 精细化工 FINE CHEMICALS 第 38 卷
[65] KANSAL D, RABNAWAZ M. Fabrication of oil- and water-resistant (精细化工), 2002, 19(8): 453-456.
paper without creating microplastics on disposal[J]. Journal of [84] CUI S (崔升), YUAN M Y (袁美玉), FU J J (付俊杰), et al.
Applied Polymer Science, 2020, 138(3): 49692-49703. Research progress of chitosan and its metal particle composite
[66] LI D D (李丹丹), TAN J H (谈继淮), HU D G (胡丁根), et al. Recent materials forantibacterial application[J/OL]. Fine Chemicals (精细化
development of waterborne polyurethane as surface sizing agent: 工), 2021, 38(9): 1757-1764, 1778.
Preparation, modification and application[J]. Chemical Industry and [85] NALINI T, BASHA S K, SADIQ A M M, et al. Development and
Engineering Progress (化工进展), 2021, 40(1): 366-377. characterization of alginate/chitosan nanoparticulate system for
[67] LI M C (李明春), XU T (许涛), XIN M H (辛梅华). Research progress hydrophobic drug encapsulation[J]. Journal of Drug Delivery Science
of antibacterial activity of chitosan and its derivatives[J]. Chemical and Technology, 2019, 52: 65-72.
Industry and Engineering Progress (化工进展), 2011, 30(1): 203-209. [86] HASSAN E A, HASSAN M L, ABOU-ZEID R E, et al. Novel
[68] ZHANG L (张玲). Antibacterial mechanism of chitosan and its nanofibrillated cellulose/chitosan nanoparticles nanocomposites films
application in food[J]. Modern Food (现代食品), 2020, (20): 71-74. and their use for paper coating[J]. Industrial Crops and Products,
[69] AMIRABAD L M, JONOOBI M, MOUSAVI N S, et al. Improved 2016, 93: 219-226.
antifungal activity and stability of chitosan nanofibers using cellulose [87] LIU R (刘仁), LU P (鲁鹏),WU M (吴敏), et al. Application progress
nanocrystal on banknote papers[J]. Carbohydrate Polymers, 2018, of nano-cellulose in gas barrier packaging materials[J]. Packaging
189: 229-237. Engineering (包装工程), 2019, 40(7): 51-59.
[70] RAGHAVENDRA G M, JUNG J, KIM D, et al. Effect of chitosan [88] LLANOS N M, MASSA A, BERNARDITA P M. Effect of beeswax
silver nanoparticle coating on functional properties of Korean content on hydroxypropyl methylcellulose-based edible film properties
traditional paper[J]. Progress in Organic Coatings, 2017, 110: 16-23. and postharvest quality of coated plums (Cv. Angeleno)[J].
[71] AL-NAAMANI L, DOBRETSOV S, DUTTA J. Chitosan-zinc oxide LWT-Food Science and Technology, 2011, 44(10): 2328-2334.
nanoparticle composite coating for active food packaging [89] WANG P, QIAN X R, SHEN J. Superhydrophobic coatings with
applications[J]. Innovative Food Science & Emerging Technologies, edible biowaxes for reducing or eliminating liquid residues of foods
2016, 38: 231-237. and drinks in containers[J]. Bioresources, 2018, 13(1): 1-2.
[72] LIU D Q (刘丹青), LU L X (卢立新), FANG J C (方家畅). [90] ZHANG W, XIAO H, QIAN L. Enhanced water vapour barrier and
Preparation and analysis of nisin-loded chitosan-starch coated grease resistance of paper bilayer-coated with chitosan and
paper[J]. Food & Machinery (食品与机械), 2017, 33(8): 106-109. beeswax[J]. Carbohydrate Polymers, 2014, 101: 401-406.
[73] YU J (俞娟), XU J H (徐俊华), FAN Y M (范一民). A review of [91] SZOCINSKI M, DAROWICKI K. Impedance evaluation of coatings
antibacterial properties of chitosan[J]. Journal of Forestry Engineering from biobased material[J]. Surface Innovations, 2018, 6(4/5): 286-294.
(林业工程学报), 2018, 3(5): 20-27. [92] KHWALDIA K, BASTA A H, ALOUI H, et al. Chitosan-caseinate
[74] LI J H, ZHUANG S L. Antibacterial activity of chitosan and its bilayer coatings for paper packaging materials[J]. Carbohydrate
derivatives and their interaction mechanism with bacteria: Current Polymers, 2014, 99: 508-516.
state and perspectives[J]. European Polymer Journal, 2020, 138: [93] CAO S (曹松), WU Z K (吴仲岿), YIN J (殷俊), et al. Reinforcing
109984.
[75] LI Z J (李志健), YANG L H (杨丽红), DU F (杜飞), et al. waterborne polyurethanes with grafting modified cellulose nanocrystals
for CNC/WPU composite coating[J]. Journal of Materials Science
Preparation of antibacterial paper with chitosan/nano silver and its and Engineering (材料科学与工程学报), 2020, 38(6): 912-916.
antibacterial effect[J]. China Pulp & Paper (中国造纸), 2019, 38(8): [94] CHI K, CATCHMARK J M. Improved eco-friendly barrier materials
22-28.
[76] AN J, JI Z, WANG D, et al. Preparation and characterization of based on crystalline nanocellulose/chitosan/carboxymethyl cellulose
polyelectrolyte complexes[J]. Food Hydrocolloids, 2018, 80: 195-205.
uniform-sized chitosan/silver microspheres with antibacterial
activities[J]. Materials Science & Engineering C—Materials for [95] HU Y H (胡永辉). Effect of chitosan/cationic starch oil repellent on
Biological Applications, 2014, 36: 33-41. the structure and performance of grease resistance packaging
[77] MIHALY COZMUTA A, APJOK R, PETER A, et al. Active papers paper[J]. Paper and Paper Making (纸和造纸), 2014, 33(1): 45-49.
coated with chitosan and containing TiO 2 and Ag/TiO 2 nanoparticles [96] WEGRZYNOWSKA-DRZYMALSKA K, GREBICKA P,
for increasing the shelf-life of walnut kernels[J]. Cellulose, 2018, MLYNARCZYK D T, et al. Crosslinking of chitosan with dialdehyde
25(9): 5205-5225. chitosan as a new approach for biomedical applications[J]. Materials,
[78] HUANG H (黄皓), LI L (李莉), QIN Y (秦雨), et al. Migration rules 2020, 13(15): 3413.
of Zn from nano-ZnO modified LDPE food packaging films[J]. [97] LYU Y (吕勇), XIAN Z W (咸政卫), SONG C (宋词), et al.
Transactions of the Chinese Society of Agricultural Engineering (农 Preparation and properties of the composite sizing agent of
业工程学报), 2018, 34(2): 278-283. dialdehyde chitosan/cationic starch[J]. Digital Printing (数字印刷),
[79] SHAHEEN T I, FOUDA A, SALEM S S. Integration of cotton 2019, (1): 94-99.
fabrics with biosynthesized CuO nanoparticles for bactericidal [98] LYU Y (吕勇). Prepartion of selective oxidation chitosan derivatives
activity in the terms of their cytotoxicity assessment[J]. Industrial & and applications in paper making[D]. Wuxi: Jiangnan University (江
Engineering Chemistry Research, 2021, 60(4): 1553-1563. 南大学), 2014.
[80] KHAN S B, ALI F, KAMAL T, et al. CuO embedded chitosan [99] CHEN J, WANG X, LONG Z, et al. Preparation and performance of
spheres as antibacterial adsorbent for dyes[J]. International Journal of thermoplastic starch and microcrystalline cellulose for packaging
Biological Macromolecules, 2016, 88: 113-119. composites: Extrusion and hot pressing[J]. International Journal of
[81] ZHAO Q (赵琪), SUN H Y (孙赫阳), HU Z W (胡子文), et al. Biological Macromolecules, 2020, 165: 2295-2302.
Preparation and application progress titania-based composite [100] FENG G D (冯国东), MA Y (马艳), JIA P Y (贾普友), et al.
photocatalyst materials[J]. Journal of Functional Materials and Chemical synthesis and application of vegetable oil-based plasticizers[J].
Devices (功能材料与器件学报), 2020, 26(2): 83-88. Journal of Forestry Engineering (林业工程学报), 2020, 5(1): 18-28.
[82] TANG Y J (唐艳军), LIU X F (刘晓峰), XIA J (夏军), et al. [101] WANG F (王芳), ZHAO Y C (赵郁聪), JIN L P (靳刘萍), et al.
Preparation of TiO 2/chitosan nanocomposited coatings and its Properties of starch-chitosan composite films by four polyols as
application in antibacterial coated paper[J]. Journal of Functional plasticizers[J]. Packaging Engineering (包装工程), 2020, 41(3):
Materials (功能材料), 2012, 43(17): 2416-2420. 128-132.
[83] JIANG Y F (蒋永福), ZHANG K (张焜), LI B N (黎碧娜). Natural [102] WANG S, JING Y. Study on the barrier properties of glycerol to
preservative—Research and development of nisin[J]. Fine Chemicals chitosan coating layer[J]. Materials Letters, 2017, 209: 345-348.