Journal of Textile Research ›› 2024, Vol. 45 ›› Issue (05): 113-120.doi: 10.13475/j.fzxb.20230500801

• Dyeing and Finishing Engineering • Previous Articles     Next Articles

Fabrication of antibacterial polymers coated cotton fabrics with I2 release for wound healing

HAN Hua, HU Anran, SUN Yiwen, DING Zuowei, LI Wei, ZHANG Caiyun, GUO Zengge()   

  1. Lutai School of Textile and Apparel, Shandong University of Technology, Zibo, Shandong 255000, China
  • Received:2023-05-04 Revised:2024-02-05 Online:2024-05-15 Published:2024-05-31

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Abstract:

Objective Using raw cotton fabrics as medical cotton dressings in wound treatment cannot effectively prevent wound infection. Cotton dressings with antibacterial function can effectively prevent wound infections, but most of the antibacterial agents used for antibacterial finishing on cotton fabric face issues of resistance and high toxicity. In order to enhance the value of medical cotton-based dressings by ensuring safe and effective disinfection of wounds on wound management, a safe and low toxicity preparation strategy is urgently needed to endow cotton materials with excellent bactericidal ability.

Method Iodophor has been widely used for wound disinfection because of its good bactericidal effect and biocompatibility. However, few studies focused on the release of I2 from cotton materials to prevent wound infections, mainly due to the low chelation strength of cotton materials to I2, making it difficult to ensure sufficient I2 release. In order to provide safe antibacterial effects to ordinary cotton materials, we selected less toxic I2 as the antibacterial active ingredient. Cotton fabrics were coated with good biocompatibility of sodium carboxymethyl cellulose (CMC)/polyvinyl pyrrolidone (PVP) hybrid polymer, adding coated cotton fabrics into potassium iodide (KI) solution until full adsorption and sufficient swelling of the cotton fabrics. After that, hydrogen peroxide with a concentration of 3% was added to oxidized KI into I2. Finally, through impregnation method, complexed I2 molecules were attached onto the surface of the coated cotton fabric.

Results Both CMC and PVP are hydrophilic polymers, and the cotton fabric coated with CMC/PVP hybrid polymer still showed good water absorption ability and were able to adsorb I2 up to 18.6 μg/mg, the existence of polyvinyl pyrrolidone made cotton fabric demonstrated a strong I2 adsorption, ensured bactericidal effect against bacteria. Owing to the excellent film-forming properties of sodium carboxymethyl cellulose (CMC), cotton fabrics coated with CMC/PVP polymers formed a smooth surface, and the PVP polymer on the surface of cotton fabrics adsorbed a large amount of I2. The inhibition zones test confirmed that cotton fabric complexing with I2 was able to continuously release I2 to form an antibacterial ring. Owing to the strong oxidation ability of I2, cotton fabric complexing with I2 was able to quickly kill bacteria in contact via destroying bacteria cell membrane. Cyto-toxicity experiments confirmed that all cotton fabrics, whether before or after coating and complexing with I2, exhibited low toxicity against fibroblasts, and the cell survival rate of all samples was above 90%. When cotton fabric was used for bacterial infection wound treatment, the released I2 killed 99.9% of bacteria at the wound tissue, significantly accelerating wound healing speed. In addition, the release of iodine ions effectively reduced the inflammatory response caused by bacterial infections, thereby accelerating wound healing.

Conclusion Finishing cotton fabric with CMC/PVP hybrid polymer coating is proven to maintain good water absorption performance and increase the chelating cap ability of cotton fabric to I2, and after complexing with I2 molecules, cotton fabric has almost no toxic effect on cellular tissues. Owing to the adsorption of full dose I2, when using cotton fabrics complexing with I2 for wound infected with bacteria, this cotton fabric can slowly release I2 to kill bacteria at the wound tissues. In summary, using this cotton fabrics releasing I2 can not only prevent wound infections but also reduce the inflammatory response caused by bacterial contamination, thereby accelerating wound healing. This cotton fabric as a medical dressing to treat wounds can effectively prevent wound infection without the need for disinfection. Therefore, this cotton fabric dressing can be a good substitute for current wound dressings and has great potential in the clinical treatment of wound infections.

Key words: cotton fabric, functional textile, antibacterial performance, medical dressing, coating modification, biocompatibility

CLC Number: 

  • TS195.5

Tab.1

Mass ratio of CMC to PVP in CMC/PVP mixed solution"

CMC/PVP
质量分数/%		 CMC 与PVP 的质量比
1.0 4∶1 3∶2 2∶3 1∶4
1.5 4∶1 3∶2 2∶3 1∶4
2.0 4∶1 3∶2 2∶3 1∶4

Fig.1

Statistical chart of water absorption performance and I2 adsorption capacity for modified cotton fabrics. (a) Water absorption performance of coated cotton fabrics;(b) I2 adsorption capacity for I2 released antibacterial coated cotton fabric"

Fig.2

SEM images of cotton fabrics. (a) Raw cotton fabric; (b) Coated cotton fabric; (c) I2 released antibacterial coated cotton fabric"

Fig.3

Analysis of surface elements on cotton fabrics. (a) EDS analysis of I2 released antibacterial coated cotton fabric; (b) Mpping analysis I2 released antibacterial coated cotton fabric"

Fig.4

Zone of bacteria inhibition for cotton fabrics. (a) S.aureus; (b) E.coli"

Fig.5

Morphological changes of S.aureus (a) and E.coli (b) on samples"

Fig.6

Fluorescent staining photos of L929 fibroblasts treated with different cotton fabrics. (a) Green fluorescent staining photos; (b) Red fluorescent staining photos"

Fig.7

Pictures of mouse skin defects healed after being treated with different cotton fabrics on different days"

Tab.2

Statistical data of healing rate and number of infected bacteria at mouse skin wounds"

样品名称 测试时间/d 愈合率/% 细菌菌落数/(CFU·mL-1)
3 1.8 12.3×106
纯棉织物 7 45.6 1 045
14 96.8
3 7.3 14.5×106
涂层棉织物 7 48.7 2 321
14 98.7
3 42.4 2 341
释放I2抗菌涂
层棉织物		 7 65.4 352
14 100.0

Fig.8

H&E images of wound tissue treated with different cotton fabric samples"

Tab.3

Tensile breaking strength and elongation values of different cotton fabric samples"

样品名称 断裂强力/N 断裂伸长率/%
经向 纬向 经向 纬向
纯棉织物 196 176 25 14
涂层棉织物 232 205 28 26
释放I2抗菌
涂层棉织物		 240 202 17 18
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