AI Chat Paper
Note: Please note that the following content is generated by AMiner AI. SciOpen does not take any responsibility related to this content.
{{lang === 'zh_CN' ? '文章概述' : 'Summary'}}
{{lang === 'en_US' ? '中' : 'Eng'}}
Chat more with AI
Powered by AMiner. Clicking this button will take you away from SciOpen.
Home Paper and Biomaterials Article
PDF (745.8 KB)
Cite
EndNote(RIS) BibTeX
Collect
Submit Manuscript AI Chat Paper
Show Outline
Outline
Show full outline
Hide outline
Outline
Show full outline
Hide outline
Invited Review | Open Access

Cellulose-based Antimicrobial Composites and Applications: A Brief Review

Bo Sun1,2Fangong Kong3Min Zhang2Weijun Wang2Birat Singh KC1Jimi Tjong1Mohini Sain1( )
Center for Biocomposites and Biomaterials Processing, Department of Mechanical and Industrial Engineering, University of Toronto, Toronto ON, M5S 3B3, Canada
Key Laboratory of Food Nutrition and Safety (Tianjin University of Science and Technology), Ministry of Education, Tianjin, 300457, China
Key Laboratory of Pulp & Paper Science and Technology of Shandong Province, Ministry of Education, Qilu University of Technology (Shandong Academy of Sciences), Ji'nan, Shandong Province, 250353, China
Show Author Information

Abstract

Cellulose-based antimicrobial composites, typically in the form of functional films and cloth, have received much attention in various applications, such as food, medical and textile industries. Cellulose is a natural polymer, and is highly biodegradable, green, and sustainable. Imparting antimicrobial properties to cellulose, will significantly enhance its applications so that its commercial value can be boosted. In this review paper, the use of cellulose for antimicrobial composites' preparation was discussed. Two different approaches: surface loading/coating and interior embedding, were focused. Three most widely-applied sectors: food, medical and textile industries, were highlighted. Nanocellulose, as a leading-edge cellulose material, its unique application on the antimicrobial composites, was particularly discussed.

Keywords

compositesantimicrobialnanocellulosecellulose-based

References

[1]

Mao H Q, Gong Y Y, Liu Y L, et al. Progress in nanocellulose preparation and application[J]. Paper and Biomaterials, 2017, 2(4): 65-76.
Crossref Google Scholar
[2]

Ma X Z, Zhang Y J, Huang J. Surface chemical modification of cellulose nanocrystals and its application in biomaterials[J]. Paper and Biomaterials, 2017, 2(4): 34-56.
Crossref Google Scholar
[3]

Sankar P K, Ramakrishnan R, Rosemary M. Biological evaluation of nanosilver incorporated cellulose pulp for hygiene products[J]. Materials Science and Engineering: C, 2016, 61: 631-637.
Crossref Google Scholar
[4]

Dong C, Ye Y, Qian L, et al. Antibacterial modification of cellulose fibers by grafting β-cyclodextrin and inclusion with ciprofloxacin[J]. Cellulose, 2014, 21(3): 1921-1932.
Crossref Google Scholar
[5]

Ying L, Ren X, Liang J. Antibacterial modification of cellulosic materials[J]. BioResources, 2015, 10(1): 1964-1985.
Google Scholar
[6]

Salmieri S, Islam F, Khan R A, et al. Antimicrobial nanocomposite films made of poly(lactic acid)-cellulose nanocrystals (PLA-CNC) in food applications: part A—effect of nisin release on the inactivation of Listeria monocytogenes in ham[J]. Cellulose, 2014, 21(3): 1837-1850.
Crossref Google Scholar
[7]

Amber R, Adnan M, Tariq A, et al. Antibacterial activity of selected medicinal plants of northwest Pakistan traditionally used against mastitis in livestock[J]. Saudi Journal of Biological Sciences, 2018, 25(1): 154-161.
Crossref Google Scholar
[8]

Yang F. Antibacterial Agent and Its Application in Antibacterial Paper[J]. China Pulp & Paper, 2006, 25(8): 51-55.
Crossref Google Scholar
[9]

Motta G J, Milne C T, Corbett L Q. Impact of antimicrobial gauze on bacterial colonies in wounds that require packing[J]. Ostomy Wound Management, 2004, 50(8): 48-62.
Google Scholar
[10]

Hoseinnejad M, Jafari S M, Katouzian I. Inorganic and metal nanoparticles and their antimicrobial activity in food packaging applications[J]. Critical Reviews in Microbiology, 2018, 44(2): 161-181.
Crossref Google Scholar
[11]

Dizaj S M, Lotfipour F, Barzegar-Jalali M, et al. Antimicrobial activity of the metals and metal oxide nanoparticles[J]. Materials Science and Engineering: C, 2014, 44: 278-284.
Crossref Google Scholar
[12]

Seyedpour S F, Rahimpour A, Najafpour G. Facile in-situ assembly of silver-based MOFs to surface functionalization of TFC membrane: a novel approach toward long-lasting biofouling mitigation[J]. Journal of Membrane Science, 2019, 573: 257-269.
Crossref Google Scholar
[13]

Saraswathi M S S A, Rana D, Alwarappan S, et al. Polydopamine layered poly(ether imide) ultrafiltration membranes tailored with silver nanoparticles designed for better permeability, selectivity and antifouling[J]. Journal of Industrial and Engineering Chemistry, 2019, 76: 141-149.
Crossref Google Scholar
[14]

Thakoersing V S, Gooris G S, Mulder A, et al. Unraveling barrier properties of three different in-house human skin equivalents[J]. Tissue Engineering Part C: Methods, 2011, 18(1): 1-11.
Crossref Google Scholar
[15]

Patil M P, Kim G-D. Eco-friendly approach for nanoparticles synthesis and mechanism behind antibacterial activity of silver and anticancer activity of gold nanoparticles[J]. Applied Microbiology and Biotechnology, 2017, 101(1): 79-92.
Crossref Google Scholar
[16]

Koduru J R, Kailasa S K, Bhamore J R, et al. Phytochemical-assisted synthetic approaches for silver nanoparticles antimicrobial applications: a review[J]. Advances in colloid and interface science, 2018, 256: 326-339.
Crossref Google Scholar
[17]

Kim K-J, Sung W S, Suh B K, et al. Antifungal activity and mode of action of silver nano-particles on Candida albicans[J]. Biometals, 2009, 22(2): 235-242.
Crossref Google Scholar
[18]

Feßler A T, Li J, Kadlec K, et al. Staphylococcus aureus[M]. The Netherlands: Elsevier, 2018: 57-85.
Crossref
[19]

Fortunati E, Mazzaglia A, Balestra G M. Sustainable control strategies for plant protection and food packaging sectors by natural substances and novel nanotechnological approaches[J]. Journal of the Science of Food and Agriculture, 2019, 99(3): 986-1000.
Crossref Google Scholar
[20]

Fan X, Ngo H, Wu C. Natural and Bio-based Antimicrobials: A Review, in Natural and Bio-Based Antimicrobials for Food Applications[M]. USA: ACS Publications, 2018: 1-24.
Crossref
[21]

Onaizi S A, Leong S S. Tethering antimicrobial peptides: current status and potential challenges[J]. Biotechnology Advances, 2011, 29(1): 67-74.
Crossref Google Scholar
[22]

Kaplan J B. Biofilm dispersal: mechanisms, clinical implications, and potential therapeutic uses[J]. Journal of Dental Research, 2010, 89(3): 205-218.
Crossref Google Scholar
[23]

Strempel N, Strehmel J, Overhage J. Potential application of antimicrobial peptides in the treatment of bacterial biofilm infections[J]. Current Pharmaceutical Design, 2015, 21(1): 67-84.
Crossref Google Scholar
[24]

Gomes A, Mano J, Queiroz J, et al. Incorporation of antimicrobial peptides on functionalized cotton gauzes for medical applications[J]. Carbohydrate Polymers, 2015, 127: 451-461.
Crossref Google Scholar
[25]

Andersson D I, Hughes D, Kubicek-Sutherland J Z. Mechanisms and consequences of bacterial resistance to antimicrobial peptides[J]. Drug Resistance Updates, 2016, 26: 43-57.
Crossref Google Scholar
[26]

Li H, Peng L. Antimicrobial and antioxidant surface modification of cellulose fibers using layer-bylayer deposition of chitosan and lignosulfonates[J]. Carbohydrate Polymers, 2015, 124: 35-42.
Crossref Google Scholar
[27]

Pisoschi A M, Pop A, Cimpeanu C, et al. Nanoencapsulation techniques for compounds and products with antioxidant and antimicrobial activity—a critical view[J]. European Journal of Medicinal Chemistry, 2018, 157: 1326-1345.
Crossref Google Scholar
[28]

Ottenhall A, Seppänen T, Ek M. Water-stable cellulose fiber foam with antimicrobial properties for bio based lowdensity materials[J]. Cellulose, 2018, 25(4): 2599-2613.
Crossref Google Scholar
[29]

Vasile B S, Oprea O, Voicu G, et al. Synthesis and characterization of a novel controlled release zinc oxide/gentamicin-chitosan composite with potential applications in wounds care[J]. International Journal of Pharmaceutics, 2014, 463(2): 161-169.
Crossref Google Scholar
[30]

Gaikwad K K, Singh S, Lee Y S. Antimicrobial and improved barrier properties of natural phenolic compound-coated polymeric films for active packaging applications[J]. Journal of Coatings Technology and Research, 2019, 16(1): 147-157.
Crossref Google Scholar
[31]

Gaikwad K K, Singh S, Lee Y S. A pyrogallol-coated modified LDPE film as an oxygen scavenging film for active packaging materials[J]. Progress in Organic Coatings, 2017, 111: 186-195.
Crossref Google Scholar
[32]

Han Y, Wang L. Sodium alginate/carboxymethyl cellulose films containing pyrogallic acid: physical and antibacterial properties[J]. Journal of the Science of Food and Agriculture, 2017, 97(4): 1295-1301.
Crossref Google Scholar
[33]

Sun B, Zhang M, Ni Y. Use of sulfated cellulose nanocrystals towards stability enhancement of gelatinencapsulated tea polyphenols[J]. Cellulose, 2018, 25(9): 5157-5173.
Crossref Google Scholar
[34]
Ren K. Synthesis of some biobased surfactants, and their functionalities as emulsifiers and antimicrobial agents[D]. Iowa: Iowa State University, 2018.
[35]

Ngo H, Fan X, Moreau R. Poly-phenolic branchedchain fatty acids as potential bio-based, odorless, liquid antimicrobial agents[J]. INFORM, 2018, 29(3): 20-22.
Crossref Google Scholar
[36]

Zhang X, Ou-yang S, Wang J, et al. Construction of antibacterial surface via layer-by-layer method[J]. Current Pharmaceutical Design, 2018, 24(8): 926-935.
Crossref Google Scholar
[37]

Xu Y, Li S, Yue X, et al. Review of silver nanoparticles (AgNPs)-cellulose antibacterial composites[J]. BioResources, 2017, 13(1): 2150-2170.
Crossref Google Scholar
[38]

Ahmad I, Kamal T, Khan S B, et al. An efficient and easily retrievable dip catalyst based on silver nanoparticles/chitosan-coated cellulose filter paper[J]. Cellulose, 2016, 23(6): 3577-3588.
Crossref Google Scholar
[39]

Hebeish A, Hashem M, El-Hady M A, et al. Development of CMC hydrogels loaded with silver nano-particles for medical applications[J]. Carbohydrate Polymers, 2013, 92(1): 407-413.
Crossref Google Scholar
[40]

Livazovic S, Li Z, Behzad A R, et al. Cellulose multilayer membranes manufacture with ionic liquid[J]. Journal of Membrane Science, 2015, 490: 282-293.
Crossref Google Scholar
[41]

Chook S W, Chia C H, Zakaria S, et al. Effective immobilization of silver nanoparticles on a regenerated cellulose-chitosan composite membrane and its antibacterial activity[J]. New Journal of Chemistry, 2017, 41(12): 5061-5065.
Crossref Google Scholar
[42]

Benavente J, Garcia M, Urbano N, et al. Inclusion of silver nanoparticles for improving regenerated cellulose membrane performance and reduction of biofouling[J]. International Journal of Biological Macromolecules, 2017, 103: 758-763.
Crossref Google Scholar
[43]

Shen Z, Cai N, Xue Y, et al. Engineering Sustainable Antimicrobial Release in Silica-Cellulose Membrane with CaCO3-aided Processing for Wound Dressing Application[J]. Polymers, 2019, 11(5): 808.
Crossref Google Scholar
[44]

Makaremi M, Pasbakhsh P, Cavallaro G, et al. Effect of morphology and size of halloysite nanotubes on functional pectin bionanocomposites for food packaging applications[J]. ACS Applied Materials & Interfaces, 2017, 9(20): 17476-17488.
Crossref Google Scholar
[45]

Rollini M, Mascheroni E, Capretti G, et al. Propolis and chitosan as antimicrobial and polyphenols retainer for the development of paper based active packaging materials[J]. Food Packaging and Shelf Life, 2017, 14: 75-82.
Crossref Google Scholar
[46]

El-Naggar M E, Shaarawy S, Shafie A E, et al. Development of antimicrobial medical cotton fabrics using synthesized nanoemulsion of reactive cyclodextrin hosted coconut oil inclusion complex[J]. Fibers and Polymers, 2017, 18(8): 1486-1495.
Crossref Google Scholar
[47]

Bhuiyan M R, Hossain M, Zakaria M, et al. Chitosan coated cotton fiber: physical and antimicrobial properties for apparel use[J]. Journal of Polymers and the Environment, 2017, 25(2): 334-342.
Crossref Google Scholar
[48]

Buşilǎ M, Muşat V, Textor T, et al. Synthesis and characterization of antimicrobial textile finishing based on Ag: ZnO nanoparticles/chitosan biocomposites[J]. RSC Advances, 2015, 5(28): 21562-21571.
Crossref Google Scholar
[49]

Jang Y-S, Amna T, Hassan M S, et al. Nanotitania/ mulberry fibers as novel textile with anti-yellowing and intrinsic antimicrobial properties[J]. Ceramics International, 2015, 41(5): 6274-6280.
Crossref Google Scholar
[50]
De France K J. Structured Cellulose Nanocrystal Composite Hydrogels for Biomedical Applications[D]. Canada: McMaster University, 2019.
[51]

Duan C, Meng J, Wang X, et al. Synthesis of novel cellulose-based antibacterial composites of Ag nanoparticles@ metal-organic frameworks@ carboxymethylated fibers[J]. Carbohydrate Polymers, 2018, 193: 82-88.
Crossref Google Scholar
[52]

Liu K, Nasrallah J, Chen L, et al. A facile template approach to preparing stable NFC/Ag/polyaniline nanocomposites for imparting multifunctionality to paper[J]. Carbohydrate Polymers, 2018, 194: 97-102.
Crossref Google Scholar
[53]

Sun B, Wang W, Zhang M, et al. Biomass-based edible film with enhanced mass barrier capacity and gas permeable selectivity[J]. Cellulose, 2018, 25(10): 5919-5937.
Crossref Google Scholar
[54]

Sun B, Hou Q, Liu Z, et al. Stability and efficiency improvement of ASA in internal sizing of cellulosic paper by using cationically modified cellulose nanocrystals[J]. Cellulose, 2014, 21(4): 2879-2887.
Crossref Google Scholar
[55]

Sun B, Hou Q, Liu Z, et al. Sodium periodate oxidation of cellulose nanocrystal and its application as a paper wet strength additive[J]. Cellulose, 2015, 22(2): 1135-1146.
Crossref Google Scholar
[56]

Sun B, Hou Q, He Z, et al. Cellulose nanocrystals (CNC) as carriers for a spirooxazine dye and its effect on photochromic efficiency[J]. Carbohydrate Polymers, 2014, 111: 419-424.
Crossref Google Scholar
[57]

Liu K, Liang H, Nasrallah J, et al. Preparation of the CNC/Ag/beeswax composites for enhancing antibacterial and water resistance properties of paper[J]. Carbohydrate Polymers, 2016, 142: 183-188.
Crossref Google Scholar
[58]

Saini S, Falco Ç Y, Belgacem M N, et al. Surface cationized cellulose nanofibrils for the production of contact active antimicrobial surfaces[J]. Carbohydrate Polymers, 2016, 135: 239-247.
Crossref Google Scholar
[59]

Sun B, Zhang M, He Z, et al. Towards greener and more sustainable cellulose-based hand sanitizer products[J]. Journal of Bioresources and Bioproducts, 2017, 2(2): 56-60.
Crossref Google Scholar
[60]

Liu K, Chen L, Huang L, et al. Enhancing antibacterium and strength of cellulosic paper by coating triclosanloaded nanofibrillated cellulose (NFC)[J]. Carbohydrate Polymers, 2015, 117: 996-1001.
Crossref Google Scholar
Paper and Biomaterials
Volume 4 Issue 4,
October 2019
Pages 1-14
DOI: 10.26599/PBM.2019.9260025
Cite this article:
Sun B, Kong F, Zhang M, et al. Cellulose-based Antimicrobial Composites and Applications: A Brief Review. Paper and Biomaterials, 2019, 4(4): 1-14. https://doi.org/10.26599/PBM.2019.9260025

486

Views

28

Downloads

0

Crossref

6

Scopus

Altmetrics
Received: 17 July 2019
Accepted: 22 August 2019
Published: 01 October 2019
© 2019 Paper and Biomaterials Editorial Board

This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/)
Return