Characterization of active food packaging films based on poly(vinyl alcohol)/boric acid/montmorillonite nanocomposite incorporated with polyphenol

Yıl 2023, Cilt: 10 Sayı: 4, 893 - 902, 11.11.2023

Serap Mutlu Yaniç , Esen Gül Ateş

Öz

Active food packaging poly(vinyl alcohol)/boric acid/montmorillonite (PVA/BA/MMT) nanocomposite films incorporated with ferulic acid (FA) were synthesized using solution casting method. The structural, thermal, transmittance, antimicrobial, and antifungal properties of nanocomposite films have been investigated. The Fourier transforms infrared (FTIR) spectroscopy used to demonstrate the chemical structure of films and interaction between boric acid (BA) and PVA.
X-Ray diffraction analysis (XRD) was performed to determine the dispersion and exfoliated of the montmorillonite in the PVA matrix. Thermal stability of PVA/BA/MMT films incorporated with FA were evaluated by using TG/DTA analyzer. Optical properties of films determined using by UV/VIS spectrophotometer at scanning percent transmittance. The antimicrobial an antifungal activity of the films incorporated with FA could inhibit bacterial growth. It has been determined that the nanocomposite films have antibacterial properties against E. coli and S. aureus and antifungal properties against C. albicans.

Anahtar Kelimeler

polyvinyl alcohol, boric acid, montmorillonite, polyphenol, packaging film

Kaynakça

• 1. Chen C, Tang Z, Ma Y, Qui W, Yang F, Mei J. Physicochemical, microstructural, antioxidant and antimicrobial properties of active packaging films based on poly(vinyl alcohol)/clay nanocomposite incorporated with tea polyphenols. Progress in Organic Coatings. 2018;123:176-184.Available from: <DOI>.
• 2. Liu G, Song Y, Wang J, Zhuang H, Ma L, Li C, et al. Effects of nanoclay type on the physical and antimicrobial properties of PVOH-based nanocomposite films. LWT – Food Science and Technology. 2014;57:562- 568. Available from: <DOI>.
• 3. Park K, Oh Y, Panda PK, Seo J. Effects of an acidic catalyst on the barrier and water resistance properties of crosslinked poly (vinyl alcohol) and boric acid films. Progress in Organic Coatings. 2022;173:107186. Available from: <DOI>.
• 4. Chen C, Chen Y, ie J, u Z, Tang Z, Yang F, Fu K. Effects of montmorillonite on the properties of cross-linked poly(vinyl alcohol)/boric acid films. Progress in Organic Coatings. 2017;112:66-74. Available from: <DOI>.
• 5. Lim M, Kwon H, Kim D, Seo J, Han H, Khan SB. Highly enhanced water resistant and oygen barrier properties of cross-linked poly(vinyl alcohol) hybrid films for packaging applications. Progress in Organic Coatings. 2015;85:68- 75. Available from: <DOI>.
• 6. Miyazaki T, Takeda Y, Akane S, Itou T, Hoshiko A, En K. Role of boric acid for a poly (vinyl alcohol) film as a cross linking agent: Melting behaviors of the films with boric acid. Polymer. 2010;51:5539-5549. Available from: <DOI>.
• 7. Balasubramaniam MP, Murugan P, Chenthamara D, et al. Synthesis of chitosan-ferulic acid conjugated poly(vinyl alcohol) polymer film for an improved wound healing. Materials Today Communications. 2020;25:101510. Available from: <DOI>.
• 8. Kokabi M, Sirousazar M, Hassan ZM. PVA–clay nanocomposite hydrogels for wound dressing. Macromolecular Nanotechnology. 2007;43:773-781. Available from: <DOI>.
• 9. Ochiai H, Fukushima S, Fujikawa M, Yamamura H. Mechanical and Thermal Properties of Poly(vinyl alcohol) Crosslinked by Borax. Polymer Jpurnal. 1976;1(8):131- 133. Available from: <DOI>.
• 10. Das Mi Ghatak S. Synthesis of boron nitride from boron containing poly(viynl alcohol) as ceramic precursor. Bulletin of Materials Science. 2012 Feb;35:99- 102. Available from: <DOI>.
• 11. Ochiai H, Fujino Y, Tadokoro Y, Murakami I. Polyelectrolyte behavior of poly(vinyl alcohol) in aqueous borax solution. Polymer Journal. 1982;14:423-426. Available from: <DOI>.
• 12. Lin, HL, Liu WH, Shen KS, Yu TL, Cheng CH. Weak Gel Behaviour of Poly(vinyl alcohol)-Borax Aqueous Solutions. Journal of Polymerr Research. 2003;10:171-179. Available from: <DOI>.
• 13. Lim M,Kwon H, Kim D, Seo J, Han H, Khan SB. Highly enhanced water resistant and oxygen barrier properties of cross-linked poly(viynl alcohol) hybrid films for packaging applications. Progress in Organic Coatings. 2015:85;68-75. Available from: <DOI>.
• 14. Woo JH, Kim NH, Kim S, Park OK, Lee JH. Effects of the addition of boric acid on the physical properties of Mene/polyvinyl alcohol (PVA) nanocomposites. Composites Part B: Engineering. 2020 Oct;199:108205. Available from: <DOI>.
• 15. Strawhecker KE, Manias E. Structure and properties of poly(vinyl alcohol)/ Na+ montmorillonite nanocomposites. Chem. Mater. 2000;12 (no. 10):2943– 2949. Available from: <DOI>.
• 16. Li C, Hou T, Vongsvivut J, Li Y, She X, She F, Gao W, Kong L. Simultaneous crystallization and decomposition of PVA/MMT composites during non-isothermal process. Thermochim. 2015;618:26–35. Available from: <DOI>.
• 17. Li C, Li Y, She X, Vongsvivut J, Li J, She F, Gao W, Kong L. Reinforcement and deformation behaviors of polyvinyl alcohol/graphene/montmorillonite clay composites. Compos. Sci. Technol. 2015;118:1–8. Available from: <DOI>.
• 18. Yang Y, Liu C, Wu H. Preparation and properties of poly(vinyl alcohol)/exfoliated α-zirconium phosphate nanocomposite films, Polym. Test. 2009;28: 371–377. Available from: <DOI>.
• 19. Johansson C, Clegg F. Effect of clay type on dispersion and barrier properties of hydrophobically modified poly(vinyl alcohol)–bentonite nanocomposites. Journal of Applied Polymer Science. 2015;132(28). Available from: <DOI>.
• 20. Andrade J. Martinez CG, Chiralt A. Physical and active properties of poly (vinyl alcohol) films with phenolic acids as affected by the processing method. Food Packaging and Shelf Life. 2022;33:100855. Available from: <DOI>.
• 21. Rodriguez-Felix F, Corte-Tarazon JA, Rochin-Wong S, et. al. Physicochemical, structural, mechanical and antioxidant properties of zein films incorporated with no ultrafiltered and ultrafiltered betalains extract from the beetroot (Beta vulgaris) bagasse with potential application as active food packaging. Journal of Food Engineering. 2022;334:111153. Available from: <DOI>.
• 22. Bhowmik S, Agyei D, Ali A. Bioactive chitosan and essential oils in sustainable active food packaging: Recent trends, mechanisms, and applications. Food Packaging and Shelf Life. 2022;34:100962. Available from: <DOI>.
• 23. Ahmed W, Haque A, Mohibbullah Md, et. al. A review on active packaging for quality and safety of foods: Current trends, applications, prospects and challenges. 2022;33:100913. Available from: <DOI>.
• 24. Abbas M, Saeed F, Anjun FM, Afzaal M, Tufail T, Bashir MS. Natural polyphenols: An overview. International Journal of Food Properties. 2017;20(8):332- 338. Available from: <DOI>.
• 25. Scalbert A, Johnson IJ, Saltmarsh M. Polyphenols: antioxidants and beyond. The American Journal of Clinical Nutrition. 2005;81(1):215-217. Available from: <DOI>.
• 26. Othman L, Slemien A. Antimicrobial Activity of Polyphenols and Alkaloids in Middle Eastern Plants. Frontiers. 2019; 10:293-298. Available from: <DOI>.
• 27. Mallakpour S, Madani M. Transparent and thermally stable improved poly (vinyl alcohol)/Cloisite Na /ZnO hybrid nanocomposite films: Fabrication, morphology and surface properties. Progress in Organic Coatings. 2012;74(3);520-525. Available from: <DOI>.
• 28. Cepeda MV.P, Nastasiienko NS, Kulik TV, Palianytsia BB , Alonso E, Aspromonte SG. Adsorption and thermal transformation of lignin model compound (ferulic acid) over HY zeolite surface studied by temperature programmed desorption mass-spectrometry, FTIR and UV–Vis spectroscopy. Microporous and Mesoporous Materials. 2023 Jan; 348:112394. Available from: <DOI>.
• 29. Qian K, Shen Z Zhang L, iang , Feng T, Zhang L. Preparation of MgF –CaF nanocomposite ceramics with high infrared transmittance. Journal of the European Ceramic Society. 2022 Dec; 42(15):7203-7208. Available from: <DOI>.
• 30. Feng Z, Xu D, Shao Z, Zhu P, Qiu J, Zhu L. Rice straw cellulose microfiber reinforcing PVA composite film of ultraviolet blocking through pre-cross-linking. Carbonhydrate Polymers. 2022 Nov;296:119886. Available from: <DOI>.
• 31. Karimi A, Daud WM. Comparison the properties of PVA/Na+-MMT nanocomposites hydrogels prepared by physical and physicochemical crossling. Polymer Composites. 2014;37(3):897-906. Available from: <DOI>.
• 32. Gaume J, Gueho CT, Cros S, et.al. Optimization of PVA clay nanocomposites for ultra-barrier multilayer encapsulation of organic solar cells. Solar Energy Materials and Solar Cells. 2012;99:240-249. Available from: <DOI>.
• 33. Krumova M, Lopez P, Benavente R, Mijangos C, Perena M. Effect of crosslinking on the mechanical and thermal properties of poly(vinyl alcohol). Polymer. 2000;41(26):9265-9272. Available from: <DOI>.
• 34. Fei Y, Wang H, Gao W, Wan Y, Fu J, Yang R. Antimicrobial activity and mechanism of PLA/TP composite nanofibrous films. 2014;105:196-202. Available from: <DOI>.
• 35. El-Gama S, El sayed AM, Abdel-Hady EE. Effect of cobalt oxide nanoparticles on the nano-scale free volume and optical properties of biodegradable CMC/PVA films. Journal of Polymer and the Environment. 2017;26:2536- 2545. Available from: <DOI>.
• 36. Strawhecker KE,, Manias E. Structure and Properties of Poly(vinyl alcohol)/Na+ Montmorillonite Nanocomposites. Chem. Matter. 2000;12:2943-2949. Available from: <DOI>.
• 37. Gao X, Li R, Hu L, Lin J, Wang Z, Yu C, Fang Y, Liu Z, Tang C, Huang Y. Preparation of boron nitride nanofibers/PVA composite foam for environmental remediation. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 2020 Nov;604:125287. Available from: <DOI>.
• 38. Mohamed MB, Heiba ZK, Imam NG. Optical and thermogravimetric analysis of Zn1-xCuxS/PVA nanocomposite films. Journal of Molecular Structure. 2018 July; 1163:442-448. Available from: <DOI>.
• 39. Mroz P, Bialas S, Mucha M, Kaczmarek H. Thermogravimetric and DSC testing of poly(lactic acid) nanocomposites. Thermochimica Acta. 2013 Dec;573:186-192. Available from: <DOI>.
• 40. Zhao W, Xu H, Yanxia L, Xu J, Luan R, Feng. Temperature-dependent transmittance nanocomposite hydrogel with high mechanical strength and controllable swelling memory behavior. European Polymer Journal. 2019 March;112:328-333. Available from: <DOI>.
• 41. Chen X, Wang M, Cheng J, Zhao C, Tang Z. High thermal conductivity, good electrical insulation, and excellent flexibility of FGN/PVA films based on a large sheet and narrow diameter distribution of fluorographene. Materials Today Chemistry. 2023 Ap; 29:101422. Available from: <DOI>.
• 42. Gou J, Lu Y, Xie M, Tang X, Chen L, Zhao J, Li G, Wang H. Antimicrobial activity in Asterceae: The selected genera characterization and against multidrug resistance bacteria. Heliyon. 2023 Ap;9(4):e14985. Available from: <DOI>.