Chitosan Application in Textile Processing
Lixia Huang, Lin Xiao* and Guang Yang*
Department of Biomedical Engineering, College of Life Science and Technology, Huazhong University of Science and Technology, China
Submission: August 04, 2018; Published: August 23, 2018
*Corresponding author: Lin Xiao, Department of Biomedical Engineering, College of Life Science and Technology, Huazhong University of Science and Technology, China, Tel: +86 15997480752; Fax: +86 27-87792265; Email: xiaol@hust.edu.cn
*Corresponding author: Guang Yang, Department of Biomedical Engineering, College of Life Science and Technology, Huazhong University of Science and Technology, China, Tel: +86 27-87793523; Fax: +86 27-87792265; Email: yang_sunny@yahoo.com
How to cite this article: Lixia Huang, Lin Xiao, Guang Yang. Chitosan Application in Textile Processing. Curr Trends Fashion Technol Textile Eng. 2018; 4(2): 555635. DOI: 10.19080/CTFTTE.2018.04.555635
Keywords
Keywords: Chitosan; Textile processing; Antibacterial finishing; Anti-wrinkle finishing; Dyeing; Antistatic finishing
Introduction
Traditional textile products from fibres such as wool, cotton, silk, polyester, etc. are unable to meet the increasing demand for aesthetics, comfort, healthcare and industrial applications. Functional fabrics possessing antibacterial, anti-wrinkle, dyeing, antistatic and other special properties have received broad attention in the textile industry and fashion world. Chitosan is a product obtained by deacetylation of chitin, which is widely distributed in nature (e.g. shellfish, insects and certain fungi). It has multiple applications in the biomedical and other areas due to its characteristics of excellent biocompatibility, biodegradability, ecological safety, non-toxicity and its versatile biological effects such as antibacterial, antifungal, antitumor activity and low immunogenicity [1,2]. Chitosan has been utilized as an eco-friendly finishing agent to develop functional fabrics in the textile industry [3,4]. This article will present brief of chitosan applications in antibacterial, anti-wrinkle, dyeing and antistatic finishing of textiles (Figure 1).
Chitosan in antibacterial finishing of textiles
Textiles provide nutrients and space for attached microorganisms, which can cause disease transmission and threaten human health. To avoid this, antibacterial treatment of textiles is of great importance. Chitosan has broad-spectrum antibacterial activity, including on Staphylococcus aureus, Escherichia coli and Bacillus subtilis [5]. There are mainly two approaches to manufacture antibacterial fabrics by using chitosan. The first approach is finishing the fabric by attaching chitosan. Aloson et al. [6] used citric acid as a cross-linking agent and sodium dihydrogen phosphate as a catalyst to graft chitosan onto cotton textiles under UV irradiation, which gave them effective antibacterial properties [6]. The second approach is to prepare antibacterial fibers, then weave these antibacterial fibers. Japan Fuji Textile Co., Ltd. developed a stable ultrafine chitosan powder with the particle size of ca. 5μm, which was subsequently added to a viscose solution for blending. Finally, fibers named chitopoly with high antibacterial properties were obtained [7].
Chitosan in anti-wrinkle finishing of textiles
Textile products from natural fibers such as silk, cotton and hemp are favored by a wide range of consumers. However, these fabrics have a rather low elasticity, tending to cause wrinkling and irreversible deformation, thus lowering the aesthetics and comfort of the products. The anti-wrinkle performance of the fabric can be improved using fiber modification, changing the fabric structure, fiber blending or finishing. Finishing with chitosan is a convenient and effective way to improve the antiwrinkle performance of the fabric. Generally, a chitosan solution is first prepared by dissolving chitosan in 1% w/v acetic acid. Then, the fabric is finished in the chitosan solution through a common dipping-rolling-baking process. The chitosan solution penetrates into the fabric fiber to form a water-insoluble protective layer on the surface of the fabric after drying, resulting in a stronger and less deformable fabric. Moreover, chitosan macromolecules fill in the fiber micro-pores, where a large number of intermolecular hydrogen bonds are formed between the hydroxyl and amino groups of chitosan and the polar residues of the fiber molecules. This strengthens the amorphous regions of the fibers and decreases their mobility, thereby providing wrinkle resistance to the fabric. In a study on anti-wrinkle finishing of cotton fabric by chitosan, it was found that the higher the content of chitosan used for finishing, the better the wrinkle resistance of the fabric [8].
Chitosan in textile dyeing and finishing
Chitosan was originally used as a dye deepening agent in the textile industry. Since it is a cationic polymer, chitosan is considered to be an ideal fixing agent for anionic dyes. Salt-free dyeing is possible by using chitosan with the help of some other additives [9]. The level dyeing effect of chitosan may be explained by the fact that the presence of chitosan leads to a uniform film on the surface of the fiber. It improves the surface properties of the fiber and reduces the Coulomb repulsion between the fiber and the anionic dyes, therefore greatly improving the dye uptake rate. The deepening effect is also due to the protonation of the free amino group on the chitosan molecule under acidic conditions. When the fabric is immersed in the chitosan solution, the positive charge of the fiber is increased, thus the repulsion force between the fiber and the anionic dyes is reduced.
Chitosan in antistatic finishing of textiles
Polyester fabrics cause clothing to cling the skin because they are prone to static electricity. Employees in industrial fields using delicate electronic instruments are required to put on antistatic workwear [10]. Therefore, the antistatic finishing of fabrics is becoming an attractive subject in the textile industry. The presence of NH3 + in the molecular structure of chitosan makes the chitosan-finished fibers have an ion-conducting function in water, which can leak the static charges generated by friction quickly. Meanwhile, electrical neutralization is produced when the charge on the chitosan molecule is opposite to the surface charge on the fiber. In addition, the presence of a large number of strong polar groups such as hydroxyl groups and amino groups on the chitosan molecules makes the chitosan molecules highly hygroscopic, forming a continuous water film on the surface of the fiber. This water film, to some extent, can dissolve carbon dioxide in the air and electrolytes in the fibers, thus indirectly increasing the electrical conductivity of the fabric surface and imparting antistatic properties to the polyester fabric [11].
Conclusion
Due to its structural characteristics, chitosan can be easily blended with conventional textile fibers such as wool, cotton, silk, and polyester with good compatibility and strong interactions. Functional textiles with antibacterial, anti-wrinkle, dyeing, and antistatic properties can be produced by using chitosan as a finishing agent or fiber modifier. The application of chitosan in the textile industry not only improves the performance and adds value to fabrics but also promotes efficient use of natural resource.
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