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Preparation of CMC-β-CD-sulfaguanidine and its application for protection of paper

  • Jun Gao , Xiaoshuang Chen , Hua Li EMAIL logo and Jiaxin Yan
Published/Copyright: February 13, 2025
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Nordic Pulp & Paper Research Journal
From the journal Nordic Pulp & Paper Research Journal Volume 40 Issue 2

Abstract

CMC-β-CD-sulfaguanidine was synthesized by saturated aqueous solution method with β-CD as carrier and sulfaguanidine as inclusion compounds based on the preparation of CMC-β-CD, through single factor and orthogonal experiment, suitable conditions for the synthesis of CMC-β-CD-sulfaguanidine was obtained. The structure of the synthesized CMC-β-CD-sulfaguanidine was characterized by infrared spectroscopy, UV spectroscopy and SEM. The inclusion compounds was applied to paper reinforcement. By testing the effects of different mass concentrations of sulfaguanidine solution on the tensile strength, tearing strength, folding times, whiteness, glossiness and antibacterial properties of the paper, the suitable conditions for coating paper were found. The results show that when inclusion concentration of 3 mg/mL is coated on the paper, its mechanical properties are improved, the glossiness is slightly increased, and the whiteness is basically unchanged, at the same time, the paper has certain antibacterial properties. CMC-β-CD-SG studied in this paper has the functions of strengthening, slow-releasing, anti-mildew and antibacterial for paper, which is an innovation of paper protection material, provides the theoretical basis and data reference, as well as a new research idea and technical approach for the development of products for paper protection.

Keywords: carboxymethyl cellulose; β-cyclodextrin; sulfaguanidine; inclusion; slow release
Corresponding author: Hua Li, School of Chemical Engineering, Zhengzhou University, Zhengzhou 450001, China, E-mail:

  1. Research ethics: Not applicable.

  2. Informed consent: Not applicable.

  3. Author contributions: The authors have accepted responsibility for the entire content of this manuscript and approved its submission.

  4. Use of Large Language Models, AI and Machine Learning Tools: None declared.

  5. Conflict of interest: All other authors state no conflict of interest.

  6. Research funding: This work was supported by Undergraduate Training Program for Innovation and Entrepreneurship in 2024, No.2024cxcy327.

  7. Data availability: The raw data can be obtained on request from the corresponding author.

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Received: 2024-09-03
Accepted: 2025-01-03
Published Online: 2025-02-13
Published in Print: 2025-06-26

© 2025 Walter de Gruyter GmbH, Berlin/Boston

Articles in the same Issue

  1. Frontmatter
  2. Bleaching
  3. The effect of xylanase on the fine structure of a bleached kraft softwood pulp
  4. Mechanical Pulping
  5. Development of handsheet mechanical properties linked to fibre distributions in two-stage low consistency refining of high yield pulp
  6. Paper Technology
  7. Analysis of finger ridges in paper manufacturing and development of a qualitative model of their formation
  8. Paper Physics
  9. Microfibrillated cellulose coatings for biodegradable electronics
  10. Paper Chemistry
  11. Preparation of CMC-β-CD-sulfaguanidine and its application for protection of paper
  12. Drying characteristics and numerical simulation of tissue paper
  13. Hemicellulose as an additive in papermaking
  14. Coating
  15. Synthesis of carboxymethyl cellulose-β∼cyclodextrin-coated sulfaguanidine and its enhanced antimicrobial efficacy for paper protection
  16. Integrating barrier chemicals into coating systems for optimized white top testliner performance
  17. Printing
  18. Quantifying optical and mechanical contributions to dot gain
  19. Packaging
  20. The impact of cellulosic pulps on thermoforming process: effects on formation time and drainage efficiency
  21. Environmental Impact
  22. Assessing the impact of substituting hypo sludge (paper pulp) in cement and introducing natural fiber in the form of human hair to enhance compressive strength in concrete
  23. Recycling
  24. Atomization numerical simulation of high solids content bamboo pulping black liquor based on VOF model
  25. A review of the fractionation and properties of lignin derived from pulping black liquor and lignocellulose pretreatment
  26. Lignin
  27. In-situ construct dynamic bonds between lignin and PBAT by epoxidized soybean oil to improve interfacial compatibility: processing, characterization, and antibacterial activity for food packaging
  28. Separation of high-yield and high-purity lignin from Elm wood using ternary deep eutectic solvents
https://doi.org/10.1515/npprj-2024-0064
Keywords for this article
carboxymethyl cellulose; β-cyclodextrin; sulfaguanidine; inclusion; slow release

Articles in the same Issue

  1. Frontmatter
  2. Bleaching
  3. The effect of xylanase on the fine structure of a bleached kraft softwood pulp
  4. Mechanical Pulping
  5. Development of handsheet mechanical properties linked to fibre distributions in two-stage low consistency refining of high yield pulp
  6. Paper Technology
  7. Analysis of finger ridges in paper manufacturing and development of a qualitative model of their formation
  8. Paper Physics
  9. Microfibrillated cellulose coatings for biodegradable electronics
  10. Paper Chemistry
  11. Preparation of CMC-β-CD-sulfaguanidine and its application for protection of paper
  12. Drying characteristics and numerical simulation of tissue paper
  13. Hemicellulose as an additive in papermaking
  14. Coating
  15. Synthesis of carboxymethyl cellulose-β∼cyclodextrin-coated sulfaguanidine and its enhanced antimicrobial efficacy for paper protection
  16. Integrating barrier chemicals into coating systems for optimized white top testliner performance
  17. Printing
  18. Quantifying optical and mechanical contributions to dot gain
  19. Packaging
  20. The impact of cellulosic pulps on thermoforming process: effects on formation time and drainage efficiency
  21. Environmental Impact
  22. Assessing the impact of substituting hypo sludge (paper pulp) in cement and introducing natural fiber in the form of human hair to enhance compressive strength in concrete
  23. Recycling
  24. Atomization numerical simulation of high solids content bamboo pulping black liquor based on VOF model
  25. A review of the fractionation and properties of lignin derived from pulping black liquor and lignocellulose pretreatment
  26. Lignin
  27. In-situ construct dynamic bonds between lignin and PBAT by epoxidized soybean oil to improve interfacial compatibility: processing, characterization, and antibacterial activity for food packaging
  28. Separation of high-yield and high-purity lignin from Elm wood using ternary deep eutectic solvents
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