Synthesis of Antimicrobial and Antioxidant Zinc Oxide Hydrogel for Drug Delivery Applications
Krithika Ramesh(1*), Jeyanthi Ponnusamy(2), Pazhanisamy Periasamy(3)
(1) Department of Chemistry, Bharathiyar University, Maruthamalai Road, Coimbatore 641046, India
(2) Department of Chemistry, Queen Mary’s College, Dr. Radha Krishna Salai, Chennai 600004, India
(3) Department of Chemistry, Sir Theagaraya College, 1047, Thiruvottiyur High Rd, Chennai 600021, India
(*) Corresponding Author
Abstract
A novel and simple method was used to synthesize antimicrobial and antioxidant porous (N-tert-butylacrylamide-co-N-vinylpyrrolidone) zinc oxide hydrogel via free radical copolymerization. The hydrogel was characterized by NMR, XRD, and SEM. Thermodynamic properties of the hydrogel were described quantitatively by the Flory-Rehner method. The results indicate that the synthesized hydrogel exhibits strong antioxidant activity, making it a potential candidate for use in preventing degenerative diseases. The antimicrobial tests showed that the hydrogel could inhibit the growth of Gram-positive and Gram-negative bacteria, as well as some pathogenic bacteria and fungi. The inhibition zones ranged from 10 to 15 mm for bacteria and from 5.2 to 9.1 mm for fungi. The reactivity ratio r1 × r2 equal to 1 confirmed ideal copolymerization showed the composition of the copolymer and the comonomer feed are same. The hydrogel's structure and reactivity are significant for constructing effective delivery systems for specific applications. Optimizing the monomer proportion could enhance hydrogel efficiency and release behavior. The hydrogel's water solubility, non-toxicity, and antioxidant properties suggest it could be safe and effective throughout the drug delivery process, contributing both passive and reactive targeting functions.
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[1] Bhandari, K.P., Sapkota, D.R., Jamarkattel, M.K., Stillion, Q., and Collins, R.W., 2023, Zinc oxide nanoparticles—solution-based synthesis and characterizations, Nanomaterials, 13 (11), 1795.
[2] Ashtaputrey, P., and Ashtaputrey, S., 2018, Study of swelling behavior and determination of swelling parameters of spherical hydrogels in water, J. Drug Delivery Ther., 8 (4), 218–222.
[3] Shah, T.V., and Vasava, D.V., 2019, A glimpse of biodegradable polymers and their biomedical applications, e-Polym., 19, 385–410.
[4] Kanmaz, N., Saloglu, D., and Hizal, J., 2019, Humic acid embedded chitosan/poly (vinyl alcohol) pH-sensitive hydrogel: Synthesis, characterization, swelling kinetic and diffusion coefficient, Chem. Eng. Commun., 206 (9), 1168–1180.
[5] Sringam, J., Pankongadisak, P., Trongsatitkul, T., and Suppakarn, N., 2022, Improving mechanical properties of starch-based hydrogels using double network strategy, Polymers, 14 (17), 3552.
[6] Fenton, O.S., Olafson, K.N., Pillai, P.S., Mitchell, M.J., and Langer, R., 2018, Advances in biomaterials for drug delivery, Adv. Mater., 30 (29), 1705328.
[7] Ibrahim, K.E., Bakhiet, A.O., Khan, A., and Khan, H.A., 2018, Recent trends in biomedical applications of nanomaterials, Biosci., Biotechnol. Res. Asia, 15 (2), 253–243.
[8] Khansary, M.A., 2016, Vapor pressure and Flory-Huggins interaction parameters in binary polymeric solutions, Korean J. Chem. Eng., 33 (4), 1402–1407.
[9] Ni, S., 2017, Nanoparticles carrying natural product for drug delivery, J. Drug Delivery Ther., 7 (3), 73–75.
[10] van der Sman, R.G.M., 2015, Biopolymer gel swelling analysed with scaling laws and Flory–Rehner theory, Food Hydrocolloids, 48, 94–101.
[11] Sen, M., Yakar, A., and Güven, O., 1999, Determination of average molecular weight between cross-links (Mc) from swelling behaviours of diprotic acid-containing hydrogels, Polymer, 40 (1), 2969–2974.
[12] Alidoust, S., Zamani, M., and Jabbari, M., 2021, Adsorption of free radical TEMPO onto Al2O3 nanoparticles and evaluation of radical scavenging activity, Free Radical Res., 55 (9-10), 937–949.
[13] Autzen, A.A.A., Beuermann, S., Drache, M., Fellows, C.M., Harrisson, S., van Herk, A.M., Hutchinson, R.A., Kajiwara, A., Keddie, D.J., Klumperman, B., Russell, G.T., 2024, IUPAC recommended experimental methods and data evaluation procedures for the determination of radical copolymerization reactivity ratios from composition data, Polym. Chem., 15 (18), 1851–1861.
[14] Koiry, B.P., and Singha, N.K., 2014, Copper-mediated controlled radical copolymerization of styrene and 2-ethylhexyl acrylate and determination of their reactivity ratios, Front. Chem., 2, 91.
[15] Contreras-López, D., Saldívar-Guerra, E., and Luna-Bárcenas, G., 2013, Copolymerization of isoprene with polar vinyl monomers: Reactivity ratios, characterization and thermal properties, Eur. Polym. J., 49 (7), 1760–1772.
[16] Yu, H., and Xing, P., 2022, Moisture absorption characterization of carbon fiber-reinforced polymer using Fickian and non-Fickian models, Polym. Compos., 43 (12), 8935–8946.
[17] Zhokh, A., and Strizhak, P., 2019, Crossover between Fickian and non-Fickian diffusion in a system with hierarchy, Microporous Mesoporous Mater., 282, 22–28.
[18] Mianehro, A., 2022, Electrospun bioscaffold based on cellulose acetate and dendrimer-modified cellulose nanocrystals for controlled drug release, Carbohydr. Polym. Technol. Appl., 9, 100187.
[19] Gilarska, A., Lewandowska-Łańcucka, J., Horak, W., and Nowakowska, M., 2018, Collagen/chitosan/hyaluronic acid–based injectable hydrogels for tissue engineering applications: Design, physicochemical, and biological characterization, Colloids Surf., B, 170, 152–162.
[20] Salari, S., Bahabadi, S.E., Samzadeh-Kermani, A., and Yosefzaei, F., 2019, In-vitro evaluation of antioxidant and antibacterial potential of green synthesized silver nanoparticles using Prosopis farcta fruit extract, Iran. J. Pharm. Res., 18 (1), 430–455.
[21] Liu, S., Li, X., and Han, L., 2022, Recent developments in stimuli‐responsive hydrogels for biomedical applications, Biosurf. Biotribol., 8 (4), 290–306.
[22] Jiang, B., Larson, J.C., Drapala, P.W., Pérez-Luna, V.H., Kang-Mieler, J.J., and Brey, E.M., 2012, Investigation of lysine acrylate containing poly(N-isopropylacrylamide) hydrogels as wound dressings in normal and infected wounds, J. Biomed. Mater. Res., Part B, 100B (3), 668–676.
[23] Luo, Y., Kirker, K.R., and Prestwich, G.D., 2000, Cross-linked hyaluronic acid hydrogel films: New biomaterials for drug delivery, J. Controlled Release, 69 (1), 169–179.
[24] Thippeswamy, M., Puttagiddappa, M.G., Thippaiah, D., and Satyanarayan, N.D., 2021, Poly(acrylamide-co-acrylic acid) synthesized, moxifloxacin drug-loaded hydrogel: Characterization and evaluation studies, J. Appl. Pharm. Sci., 11 (2), 74–81.
[25] Naeem, F., Khan, S., Jalil, A., Ranjha, N.M., Riaz, A., Haider, M.S., Sarwar, S., Saher, F., and Afzal, S., 2017, pH responsive cross-link polymeric matrices based on natural polymers: Effect of process variables on swelling characterization and drug delivery properties, BioImpacts, 7 (3), 177–192.
DOI: https://doi.org/10.22146/ijc.85663
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