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Enhanced Activity and Stability of Lipase via Immobilization in Pectin-Based Hydrogels | ||
| Challenges in Nano and Micro Scale Science and Technology | ||
| مقاله 5، دوره 13، شماره 2، آذر 2025، صفحه 89-96 اصل مقاله (1.33 M) | ||
| نوع مقاله: Original Research Paper | ||
| شناسه دیجیتال (DOI): 10.22111/cnmst.2026.54762.1284 | ||
| نویسندگان | ||
| Ali Maleki؛ Arastoo Badoei-Dalfrad* ؛ Zahra Karami | ||
| Department of Biology, Faculty of Sciences, Shahid Bahonar University of Kerman, Kerman, Iran | ||
| چکیده | ||
| Pectin-based hydrogels are hydrophilic polymeric networks created from the cross-linking of the plant-based polysaccharide pectin. In this study, the hydrogels were synthesized using chemical modification with glycidyl methacrylate and used for the immobilization of Aspergillus Niger lipase (ANL). The immobilization efficiency and relative activity recovery achieved about 82% and 88.3%, respectively. Scanning electron microscopy revealed the porous three-dimensional structure of the pristine hydrogels, and the surface became rougher and the pore structure changed during the immobilization of the lipase enzymes, indicating the successful immobilization of the enzymes within the hydrogels. Fourier transform infrared spectroscopy confirmed the presence of the enzyme within the hydrogels, with the presence of the carbonyl and amide groups at 1650 and 1540 cm⁻¹, respectively. While, the functional groups of the pectin-based hydrogels remaining intact during the immobilization process. At 60°C, the immobilized lipase showed 15% of its original temperature stability compared to 5% for the free lipase. At pH 5, the immobilized enzyme was found to have 70% of its maximum pH activity, while the free enzyme was found to have 52% of its maximum pH activity. These results indicate pectin hydrogels are effective supports for lipase immobilization, improving enzyme stability for biocatalytic applications. | ||
| کلیدواژهها | ||
| Pectin hydrogel؛ Lipase؛ Immobilization؛ Scanning electron microscopy؛ FTIR | ||
| مراجع | ||
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[1] Aghajani, M., Garshasbi, H.R., Naghib, S.M. and Mozafari, M.R. 3D Printing of Hydrogel Polysaccharides for Biomedical Applications: A Review. Biomedicines, 13(3), 2025; p.731.
[2] Said, N.S., Olawuyi, I.F. and Lee, W.Y. Pectin hydrogels: Gel-forming behaviors, mechanisms, and food applications. Gels. 2023;9(9): 732-760. [3] Ghosh, R.N., Thomas, J., Janardanan, A., Namboothiri, P.K. and Peter, M. An insight into synthesis, properties and applications of gelatin methacryloyl hydrogel for 3D bioprinting. Materials Advances, 2023; 4(22):5496-5529. [4] Hasanah, U., Sani, N.D.M., Heng, L.Y., Idroes, R. and Safitri, E. Construction of a hydrogel pectin-based triglyceride optical biosensor with immobilized lipase enzymes. Biosensors, 2019; 9(4):135-146. [5] Cargnin, M.A., de Souza, A.G., de Lima, G.F., Gasparin, B.C., dos Santos Rosa, D. and Paulino, A.T. Pinus residue/pectin-based composite hydrogels for the immobilization of β-D-galactosidase. International journal of biological macromolecules. 2020; 149:773-782. [6] Cargnin, M.A., Gasparin, B.C. and Paulino, A.T. Hydrolysis of lactose using β-D-galactosidase immobilized in pectin-based hydrogels: Modeling and optimization by factorial design. LWT, 2020;132: 109836. [7] Chelpanova, T.I. and Efimtseva, E.A. Alkaline phosphatase immobilization on spherical pectin gel particles. Applied biochemistry and microbiology, 2016;52(1):36-42. [8] Costas, L., Bosio, V.E., Pandey, A. and Castro, G.R. Effects of organic solvents on immobilized lipase in pectin microspheres. Applied biochemistry and biotechnology, 2008;151(2):578-586. [9] Muanruksa, P., Dujjanutat, P. and Kaewkannetra, P. Entrapping immobilization of lipase on biocomposite hydrogels toward for biodiesel production from waste frying acid oil. Catalysts, 2020;10(8): 834-852. [10]Zhang, G., Huang, B., Zheng, C., Chen, Q. and Fei, P. Investigation of a lipase-catalyzed reaction between pectin and salicylic acid and its isomers and evaluation of the emulsifying properties, antioxidant activities, and antibacterial activities of the corresponding products. Journal of agricultural and food chemistry, 2020; 69(4):1234-1241. [11]das Neves, A.M., Visioli, L.J., Enzweiler, H. and Paulino, A.T., Lipase from Candida rugosa incorporated in pectin hydrogel via immobilization for hydrolysis of lipids in dairy effluents and production of fatty acids. Journal of Water Process Engineering, 2024; 58:104821. [12]Cargnin, M.A., Gasparin, B.C., dos Santos Rosa, D. and Paulino, A.T. Performance of lactase encapsulated in pectin-based hydrogels during lactose hydrolysis reactions. Lwt, 2021; 150: 111863. [13]Riyamol, Gada Chengaiyan, J., Rana, S.S., Ahmad, F., Haque, S. and Capanoglu, E., Recent advances in the extraction of pectin from various sources and industrial applications. ACS omega, 2023;8(49):46309-46324. [14]Maroufi, L.Y., Rashidi, M., Tabibiazar, M., Mohammadi, M., Pezeshki, A. and Ghorbani, M. Recent advances of macromolecular hydrogels for enzyme immobilization in the food products. Advanced Pharmaceutical Bulletin, 2021; 12(2): 309-318. [15]Badoei-Dalfard, A., Tahami, A. and Karami, Z. Lipase immobilization on glutaraldehyde activated graphene oxide/chitosan/cellulose acetate electrospun nanofibrous membranes and its application on the synthesis of benzyl acetate. Colloids and Surfaces B: Biointerfaces, 2022; 209:112151. [16]Badoei-Dalfard, A., Karami, Z. and Malekabadi, S., Construction of CLEAs-lipase on magnetic graphene oxide nanocomposite: an efficient nanobiocatalyst for biodiesel production. Bioresource technology, 2019; 278:473-476. [17]Mohammadi-Mahani, H., Badoei-dalfard, A. and Karami, Z. Synthesis and characterization of crosslinked lipase-metal hybrid nanoflowers on graphene oxide with increasing the enzymatic stability and reusability. Biochemical Engineering Journal, 2021; 172:108038. [18]Abdelaziz, A.A., Abo-Kamar, A.M., Elkotb, E.S. and Al-Madboly, L.A., Microbial lipases: advances in production, purification, biochemical characterization, and multifaceted applications in industry and medicine. Microbial Cell Factories, 2025; 24(1): 40-60. [19]Badoei-dalfard, A., Malekabadi, S., Karami, Z. and Sargazi, G. Magnetic cross-linked enzyme aggregates of Km12 lipase: A stable nanobiocatalyst for biodiesel synthesis from waste cooking oil. Renewable energy. 2019; 141:874-882. [20]Batista, K.A., Purcena, L.L., Alves, G.L. and Fernandes, K.F. A pectin–lipase derivative as alternative copolymer for lipase assay. Journal of Molecular Catalysis B: Enzymatic, 2014; 102: pp.25-32. [21]Beigi, P., Ganjali, F., Hassanzadeh-Afruzi, F., Salehi, M.M. and Maleki, A., 2023. Enhancement of adsorption efficiency of crystal violet and chlorpyrifos onto pectin hydrogel@ Fe3O4-bentonite as a versatile nanoadsorbent. Scientific Reports, 13(1), p.10764. [22]Malekabadi, S., Badoei-Dalfard, A. and Karami, Z. Biochemical characterization of a novel cold-active, halophilic and organic solvent-tolerant lipase from B. licheniformis KM12 with potential application for biodiesel production. International journal of biological macromolecules, 2018;109: 389-398. [23]Bradford, M.M. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Analytical biochemistry, 1976; 72(1-2): 248-254. [24]Bebiano, L. B., Presa, R., Vieira, F., Lourenço, B. N., & Pereira, R. F. (2024). Bioinspired and photoclickable thiol-ene bioinks for the extrusion bioprinting of mechanically tunable 3D skin models. Biomimetics, 9(4), 228. [25]Liu, C., Zhang, L., Tan, L., Liu, Y., Tian, W. and Ma, L., Immobilized crosslinked pectinase preparation on porous ZSM-5 zeolites as reusable biocatalysts for ultra-efficient hydrolysis of β-glycosidic bonds. Frontiers in Chemistry, 2021; 9: p.677868. [26]Muanruksa, P., Dujjanutat, P. and Kaewkannetra, P., Entrapping immobilization of lipase on biocomposite hydrogels toward for biodiesel production from waste frying acid oil. Catalysts, 2020; 10(8): p.834. [27]Abdel-Mageed, H.M., Nada, D., Radwan, R.A., Mohamed, S.A. and Gohary, N.A.E. Optimization of catalytic properties of Mucor racemosus lipase through immobilization in a biocompatible alginate gelatin hydrogel matrix for free fatty acid production: a sustainable robust biocatalyst for ultrasoundassisted olive oil hydrolysis. 3 Biotech, 2022; 12(11): p.285. [28]Li, T., Li, S., Wang, N., Tain L. Immobilization and stabilization of pectinase by multipoint attachment onto an activated agar-gel support. Food chemistry. 2008;109(4):703-8.
[29]Adetunji, A.I. and Olaniran, A.O. Biocatalytic profiling of free and immobilized partially purified alkaline protease from an autochthonous Bacillus aryabhattai Ab15-ES. Reactions, 2023; 4(2): 231-245. [30]Chalella Mazzocato, M. and Jacquier, J.C. Recent advances and perspectives on food-grade immobilization systems for enzymes. Foods, 2024; 13(13): 2127. | ||
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