Employing Monocholorotriazine β-cyclodextrin to improve Wool-containing Fabrics' Reactive/Disperse Printability and Antibacterial Properties | ||||
| International Design Journal | ||||
| Article 14, Volume 13, Issue 1 - Serial Number 50, January and February 2023, Page 161-167 PDF (846.77 K) | ||||
| Document Type: Original Article | ||||
| DOI: 10.21608/idj.2022.170719.1054 | ||||
 View on SCiNiTO | ||||
| Author | ||||
Heba Mohamed Khalil 
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| Applied arts.Helwan Univerisity | ||||
| Abstract | ||||
| -Background and problem :Natural fibres,offer the right environment and surface for the harboring and growth of harmful microorganisms like bacteria, etc., which facilitates cross-infection, the development of objectionable odors, and discoloration, deterioration of fabric. To reduce/avoid disease, prevent the growth of odors, and protect the textile material itself from microbial infection, the antibacterial operation of natural fiber textile material is attracting more attention as a method of protecting the textile material itself from microbial contamination. This is done by using appropriate antimicrobial agents with the capacity to either kill or block biologically static, the growth of harmful bacteria. Furthermore, in the textile finishing field, complexation is the long-term fixing of β-Cyclodextrin derivatives to textile surfaces with a wide range of dyestuffs and/or botanical extracts within their hydrophobic cavities for the generation of improved quality colored and/or functionalized textile products. -The main task and results of the research: The study was to show the beneficial effects of loading MCT-βCD onto/into wool, cotton/wool (C/W), viscose/wool (V/W), and polyester/wool (PET/W) blended fabrics on improving its post-printing and improving the antimicrobial activities of the procured prints. Results revealed that: 1-The best method for producing Resocoton Red G prints with outstanding antibacterial capabilities against bacteria was the proposed substrates were pre-modified with MCT- βCD, followed by Resocoton Red G printing, then post-finished with antibacterial agent. 2-SEM imaging patterns for certain fabric samples supported the differences between treated and untreated fabrics in terms of Ag element loading and fabric surface morphology. | ||||
| Keywords | ||||
| Wool containing fabric; MCT-βCD; Pre-modification; Reactive/ Disperse printing; Post- antimicrobial finishing | ||||
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| References | ||||
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1- Ibrahim, N. A. (2011). 4 - Dyeing of textile fibre blends A2 - Clark, M. Handbook of Textile and Industrial Dyeing, 2, 147-172: Woodhead Publishing.
2- Ibrahim, N. A., Abdalla, W. A., El-Zairy, E. M. R., & Khalil, H. M. (2013). Utilization of monochloro-triazine β-cyclodextrin for enhancing printability and functionality of wool. Carbohydrate Polymers, 92(2), 1520-1529.
3- Ibrahim, N. A., Eid, B. M., & El-Batal, H. (2012). A novel approach for adding smart functionalities to cellulosic fabrics. Carbohydrate Polymers, 87(1), 744-751.
4- Gao, Y., & Cranston, R. (2008). Recent Advances in Antimicrobial Treatments of Textiles. Textile Research Journal, 78(1), 60-72.
5- Holme, I. (2007). Innovative technologies for high performance textiles. Coloration Technology, 123(2), 59-73.
6- Ibrahim, N. A. (2015). Chapter 12 - Nanomaterials for Antibacterial Textiles A2 - Rai, Mahendra. In K. Kon (Ed.). Nanotechnology in Diagnosis, Treatment and Prophylaxis of Infectious Diseases (pp. 191-216). Boston: Academic Press.
7- Zhao, Y., Xu, Z., & Lin, T. (2016). 12 - Barrier textiles for protection against microbes A2 - Sun, Gang. Antimicrobial Textiles (pp. 225-245): Woodhead Publishing.
8- Cusola, O., Tabary, N., Belgacem, M. N., & Bras, J. (2013). Cyclodextrin functionalization of several cellulosic substrates for prolonged release of antibacterial agents. Journal of Applied Polymer Science, 129(2), 604-613.
9- Haji, A., Khajeh Mehrizi, M., & Akbarpour, R. (2015). Optimization of β-cyclodextrin grafting on wool fibers improved by plasma treatment and assessment of antibacterial activity of berberine finished fabric. Journal of Inclusion Phenomena and Macrocyclic Chemistry, 81(1), 121-133.
10- Ibrahim, N. A., El-Zairy, E. M. R., Abdalla, W. A., & Khalil, H. M. (2013). Combined UV-protecting and reactive printing of Cellulosic/wool blends. Carbohydrate Polymers, 92(2), 1386-1394.
11- Ibrahim, N. A., Eid, B. M., & Khalil, H. M. (2015). Cellulosic/wool pigment prints with remarkable antibacterial functionalities. Carbohydrate Polymers, 115, 559-567.
12- Radu, C.-D., Parteni, O., & Ochiuz, L. (2016). Applications of cyclodextrins in medical textiles- review. Journal of Controlled Release, 224, 146-157.
13- Ibrahim, N. A., Khalil, H. M., Eid, B. M. and Tawfik, T.M. (2018). Application of MCT-βCD to Modify Cellulose/Wool Blended Fabrics for Upgrading Their Reactive Printability and Antibacterial Functionality, Fibers and Polymers 19(8), 1655-1662.
14- Khalil. H. M. (2022). Facile Approach to Enhance Disperse Printability and Antibacterial Functionality of Wool/Polyester fabric, Egyptian Journal of Chemistry, 65(3) (2022) 447 – 454.
15- Vogel, A. I. (1975). Elementary Practical Inorganic Chemistry. London: Longman.
16- Judd, D., & Wyszeck, G. (1975). Color in Business, Science, and Industry. Wiley-Interscience; 3rd edition.
17- Ibrahim, N. A. & El-Zairy, E. M. R. (2009), Union disperse printing and UV-protecting of wool/polyester blend using a reactive β-cyclodextrin. Carbohydrate Polymers, 78, 244-249.
18- Simoncic, B. & Tomsic, B. (2010). Structure of novel antimicrobial agents for textiles, A Review. Text. Res. J., 80, 1721-1737.
19- Radetic, M. (2013). Functionalization of textile materials with silver nanoparticles. J. Mater. Sci., 48 (1), 95-107.
20- Dastjerdi R. & Montazer, M. (2010). A review on the application of inorganic nano-structured materials in the modification of textiles: focus on anti-microbial properties, Colloids and surfaces B: Biointerfaces, 79, 5-18.
21- Jones, C. M. & Hoek, E. M. V. (2010). A review of the antibacterial effect of silver nanomaterials and potential implications for human health and the environment, J. Nanopart. Res., 12, 1531-1551.
22- Simoncic, B. & Tomsic, B. (2010). Structure of novel antimicrobial agents for textiles, A Review. Text. Res. J., 80, 1721-1737.
23- Marambio-Jones, C., & Hoek, E. M. V. (2010). A review of the antibacterial effects of silver nanomaterials and potential implications for human health and the environment. Journal of Nanoparticle Research, 12(5), 1531-1551.
24- M. Radetić, Functionalization of textile materials with silver nanoparticles, Journal of Materials Science 48(1) (2013) 95-107.
25- Ibrahim, N.A., Abdel-Aziz, M. S., Eid, B. M. (2014). Biosynthesized Silver Nanoparticles for Antibacterial Treatment of Cellulosic Fabrics Using O2-Plasma, AATCC Journal of Research 1(1) 6-12.
Ibrahim, N. A., Aly, A.A., Eid, B. M. and Fahmy, H. M. (2018). Green Approach for Multifunctionalization of Cellulose-Containing Fabrics, Fibers and Polymers 19(11) 2298-2306. | ||||
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