Preparation and properties of antibacterial PVA@MCC composite membrane assisted by ionic liquids and DMSO

doi:10.1016/j.cjche.2024.10.039

Abstract

Abstract: The composite membrane of microcrystalline cellulose (MCC) with polyvinyl alcohol (PVA) was effectively synthesized using ionic liquids (ILs) as the solvent and dimethyl sulfone (DMSO) as the co-solvent through the phase conversion method. The effects of IL structure and the IL/DMSO mass ratio on the solubility of MCC were investigated. The findings indicated that the composite solvent functioned as a non-derivative solvent for MCC dissolution. The inclusion of DMSO decreased the viscosity of ILs and enhanced the rate of MCC dissolution. The solubility of MCC reached 14.5% (mass) when the mass ratio of [Bmim]Cl to DMSO was 1:1. The fabricated MCC membrane exhibited a smooth surface and a dense structure. PVA@MCC demonstrated exceptional mechanical properties and a uniform structure at a mass ratio of 2:1, with an elongation at break of 76% and a tensile strength of 14.6 MPa. The effects of antibacterial agents on the morphology, transmittance, mechanical properties, and antibacterial efficiency of PVA@MCC were investigated. The findings revealed that PVA@MCC fortified with clove oil showcased a flat and smooth surface, devoid of stratification or aggregation, and demonstrated superior mechanical properties compared to its counterparts with chitosan and ZnO additions. The elongation at break of PVA@MCC with clove oil increased to 137.6%, while its tensile strength decreased to 10.4 MPa. PVA@MCC with clove oil exhibited an antibacterial efficiency exceeding 68% against Escherichia coli, Staphylococcus aureus, and Pseudomonas aeruginosa, thereby extending the shelf life of cherry tomatoes by an additional four days at ambient temperature.

Key words: Microcrystalline cellulose, Composite membrane, Ionic liquid, Antibacterial efficiency, Mechanical property

摘要： The composite membrane of microcrystalline cellulose (MCC) with polyvinyl alcohol (PVA) was effectively synthesized using ionic liquids (ILs) as the solvent and dimethyl sulfone (DMSO) as the co-solvent through the phase conversion method. The effects of IL structure and the IL/DMSO mass ratio on the solubility of MCC were investigated. The findings indicated that the composite solvent functioned as a non-derivative solvent for MCC dissolution. The inclusion of DMSO decreased the viscosity of ILs and enhanced the rate of MCC dissolution. The solubility of MCC reached 14.5% (mass) when the mass ratio of [Bmim]Cl to DMSO was 1:1. The fabricated MCC membrane exhibited a smooth surface and a dense structure. PVA@MCC demonstrated exceptional mechanical properties and a uniform structure at a mass ratio of 2:1, with an elongation at break of 76% and a tensile strength of 14.6 MPa. The effects of antibacterial agents on the morphology, transmittance, mechanical properties, and antibacterial efficiency of PVA@MCC were investigated. The findings revealed that PVA@MCC fortified with clove oil showcased a flat and smooth surface, devoid of stratification or aggregation, and demonstrated superior mechanical properties compared to its counterparts with chitosan and ZnO additions. The elongation at break of PVA@MCC with clove oil increased to 137.6%, while its tensile strength decreased to 10.4 MPa. PVA@MCC with clove oil exhibited an antibacterial efficiency exceeding 68% against Escherichia coli, Staphylococcus aureus, and Pseudomonas aeruginosa, thereby extending the shelf life of cherry tomatoes by an additional four days at ambient temperature.

关键词: Microcrystalline cellulose, Composite membrane, Ionic liquid, Antibacterial efficiency, Mechanical property

Pengcheng Hu, Aonan Lai, Shufeng Zhou. Preparation and properties of antibacterial PVA@MCC composite membrane assisted by ionic liquids and DMSO[J]. Chinese Journal of Chemical Engineering, 2025, 79(3): 72-80.

Pengcheng Hu, Aonan Lai, Shufeng Zhou. Preparation and properties of antibacterial PVA@MCC composite membrane assisted by ionic liquids and DMSO[J]. 中国化学工程学报, 2025, 79(3): 72-80.

References

[1] Z.X. Sun, W. Thielemans, Interconnected and high cycling stability polypyrrole supercapacitors using cellulose nanocrystals and commonly used inorganic salts as dopants, J. Energy Chem. 76 (2023) 165-174.
[2] M.M. Liu, S.D. Tong, Z.H. Tong, Y.W. Guan, Y.N. Sun, A strong, biodegradable and transparent cellulose-based bioplastic stemmed from waste paper, J. Appl. Polym. Sci. 140 (13) (2023) e53671.
[3] J.H. Xu, Y.J. Zou, L. Liu, J. Yu, Z.G. Wang, Y.M. Fan, O.J. Rojas, Multifunctional aqueous ferrofluid stabilized by cellulose nanofibrils with long term stability, Chem. Eng. J. 443 (2022) 136252.
[4] Z.X. Chen, Y. Lu, R. Manica, J.T. Lu, D. Shi, J.Q. Li, Q.X. Liu, Cellulose-based slippery covalently attached liquid surfaces for synergistic rain and solar energy harvesting, Nanoscale 15 (18) (2023) 8158-8168.
[5] Y.S. Wu, H.T. Wang, J.B. Peng, M.Y. Ding, Advances in catalytic valorization of cellulose into value-added chemicals and fuels over heterogeneous catalysts, Catal. Today 408 (2023) 92-110.
[6] Q.Q. Chen, D.F. Ying, Y.W. Chen, H.X. Xie, H.R. Zhang, C.Y. Chang, Highly transparent, hydrophobic, and durable anisotropic cellulose films as electronic screen protectors, Carbohydr. Polym. 311 (2023) 120735.
[7] B.N. Kuznetsov, I.G. Sudakova, N.V. Garyntseva, A.M. Skripnikov, A.V. Pestunov, E.V. Gnidan, Birch wood biorefinery into microcrystalline, microfibrillated, and nanocrystalline celluloses, xylose, and adsorbents, Wood Sci. Technol. 57 (1) (2023) 173-196.
[8] H.B. Yuan, R.C. Tang, C.B. Yu, Microcrystalline cellulose modified by phytic acid and condensed tannins exhibits excellent flame retardant and cationic dye adsorption properties, Ind. Crops Prod. 184 (2022) 115035.
[9] B. Xiong, P.P. Zhao, K. Hu, L.N. Zhang, G.Z. Cheng, Dissolution of cellulose in aqueous NaOH/urea solution: Role of urea, Cellulose 21 (3) (2014) 1183-1192.
[10] J. Cai, L.N. Zhang, Rapid dissolution of cellulose in LiOH/urea and NaOH/urea aqueous solutions, Macromol. Biosci. 5 (6) (2005) 539-548.
[11] H.M. Yuan, J.F. Wu, D. Wang, L.L. Huang, L.H. Chen, S. Lin, Ultra-high-strength composite films prepared from NMMO solutions of bamboo-derived dissolving pulp and chitosan, Ind. Crops Prod. 170 (2021) 113747.
[12] Q.Q. Han, X. Gao, H. Zhang, K.L. Chen, L.C. Peng, Q.M. Jia, Preparation and comparative assessment of regenerated cellulose films from corn (Zea mays) stalk pulp fines in DMAc/LiCl solution, Carbohydr. Polym. 218 (2019) 315-323.
[13] Y.W. Liu, S. Jing, D. Carvalho, J.J. Fu, M. Martins, A. Cavaco-Paulo, Cellulose dissolved in ionic liquids for modification of the shape of keratin fibers, ACS Sustainable Chem. Eng. 9 (11) (2021) 4102-4110.
[14] R. Alayoubi, N. Mehmood, E. Husson, A. Kouzayha, M. Tabcheh, L. Chaveriat, C. Sarazin, I. Gosselin, Low temperature ionic liquid pretreatment of lignocellulosic biomass to enhance bioethanol yield, Renew. Energy 145 (2020) 1808-1816.
[15] G.A.S. Haron, H. Mahmood, H.B. Noh, M. Goto, M. Moniruzzaman, Cellulose nanocrystals preparation from microcrystalline cellulose using ionic liquid-DMSO binary mixture as a processing medium, J. Mol. Liq. 346 (2022) 118208.
[16] R.P. Swatloski, S.K. Spear, J.D. Holbrey, R.D. Rogers, Dissolution of cellulose [correction of cellose] with ionic liquids, J. Am. Chem. Soc. 124 (18) (2002) 4974-4975.
[17] Y.X. Cheng, W.G. Tian, Q.Y. Mi, X.J. Zheng, J. Zhang, Highly transparent all-polysaccharide composite films with tailored transmission haze for light manipulation, Adv. Mater. Technol. 5 (9) (2020) 2000378.
[18] D.S. Zhao, L.L. Fu, P.B. Ren, J.P. Li, H. Li, The dissolution of cellulose in N-allylpyridinium chloride ionic liquid/organic solvent, Polym. Mater. Sci. Eng. 28 (2012) 31-34.
[19] T. Yao, J.L. Song, C. Zhou, X.Q. Shi, Recent progress of the applications of functionalized magnetic ionic liquids in sample pretreatment, Sep. Purif. Technol. 341 (2024) 126979.
[20] T. Yao, C.L. Feng, H.L. Yan, Current developments and applications of smart polymers based aqueous two-phase systems, Microchem. J. 204 (2024) 111170.
[21] L.H. Zhang, C. Huang, C.R. Zhang, H. Pan, Swelling and dissolution of cellulose in binary systems of three ionic liquids and three co-solvents, Cellulose 28 (8) (2021) 4643-4653.
[22] Y.H. Wu, Q. Li, X.Z. Zhang, Y. Li, B. Li, S.L. Liu, Cellulose-based peptidopolysaccharides as cationic antimicrobial package films, Int. J. Biol. Macromol. 128 (2019) 673-680.
[23] I. Hongrattanavichit, D. Aht-Ong, Antibacterial and water-repellent cotton fabric coated with organosilane-modified cellulose nanofibers, Ind. Crops Prod. 171 (2021) 113858.
[24] D. Ren, Y. Wang, H.K. Wang, D. Xu, X.Y. Wu, Fabrication of nanocellulose fibril-based composite film from bamboo parenchyma cell for antimicrobial food packaging, Int. J. Biol. Macromol. 210 (2022) 152-160.
[25] L. Veronica Cabanas-Romero, C. Valls, S.V. Valenzuela, M. Blanca Roncero, F.I. Javier Pastor, P. Diaz, J. Martinez, Bacterial cellulose-chitosan paper with antimicrobial and antioxidant activities, Biomacromolecules 21 (4) (2020) 1568-1577.
[26] M. Simsek, B. Eke, H. Demir, Characterization of carboxymethyl cellulose-based antimicrobial films incorporated with plant essential oils, Int. J. Biol. Macromol. 163 (2020) 2172-2179.
[27] H. Zhang, Y.G. Xu, Y.Q. Li, Z.X. Lu, S.L. Cao, M.Z. Fan, L.L. Huang, L.H. Chen, Facile cellulose dissolution and characterization in the newly synthesized 1, 3-diallyl-2-ethylimidazolium acetate ionic liquid, Polymers 9 (10) (2017) 526.
[28] L.H. Li, Y. Zhang, Y.L. Sun, S. Sun, G.C. Shen, P. Zhao, J.Q. Cui, H.Y. Qiao, Y.M. Wang, H.M. Zhou, Manufacturing pure cellulose films by recycling ionic liquids as plasticizers, Green Chem. 22 (12) (2020) 3835-3841.
[29] E.W. Leng, Y. Zhang, Y. Peng, X. Gong, M. Mao, X.M. Li, Y. Yu, In situ structural changes of crystalline and amorphous cellulose during slow pyrolysis at low temperatures, Fuel 216 (2018) 313-321.
[30] T. Dobre, C.A.M. Patrichi, O.C. Parvulescu, A.A.A. Aljanabi, Pervaporation of aqueous ethanol solutions through rigid composite polyvinyl-alcohol/bacterial cellulose membranes, Processes 9 (3) (2021) 437.
[31] H.J. Xiu, F.Y. Ma, J.B. Li, X. Zhao, L.H. Liu, P. Feng, X. Yang, X.F. Zhang, E. Kozliak, Y. Ji, Using fractal dimension and shape factors to characterize the microcrystalline cellulose (MCC) particle morphology and powder flowability, Powder Technol. 364 (2020) 241-250.
[32] R. Katakojwala, S.V. Mohan, Microcrystalline cellulose production from sugarcane bagasse: Sustainable process development and life cycle assessment, J. Clean. Prod. 249 (2020) 119342.
[33] T.G. Ambaye, M. Vaccari, S. Prasad, E.D. van Hullebusch, S. Rtimi, Preparation and applications of chitosan and cellulose composite materials, J. Environ. Manage. 301 (2022) 113850.
[34] P.L. Bhutiya, M.S. Mahajan, M. Abdul Rasheed, M. Pandey, S. Zaheer Hasan, N. Misra, Zinc oxide nanorod clusters deposited seaweed cellulose sheet for antimicrobial activity, Int. J. Biol. Macromol. 112 (2018) 1264-1271.