Document Type : Original research
Author
Senior lecturer,Industrial Design Packaging Technologies and Expertise Department, Federal State Budgetary Educational Institution of Higher Education Russian Biotechnological University (BIOTECH University), 125080, Russia, Moscow
Abstract
The aim of this study is to encourage a shift in industry towards using natural, biodegradable materials with antimicrobial properties to produce polymeric materials that can be used effectively in areas such as food and pharmaceutical packaging. In this study, polymeric films based on low-density polyethylene (LDPE) were produced using extrusion technology with the addition of marjoram powder at concentrations of 1%, 3% and 5%. The second phase of the study involved determining the technological properties of the obtained films, including their antimicrobial, barrier, physical, and mechanical properties. The results of the research showed that polyethylene samples supplemented with marjoram powder exhibited antimicrobial properties against Bacillus subtilis and Candida albicans at concentrations of 3% and 5%. However, the same samples did not exhibit any antimicrobial properties against Escherichia coli and Aspergillus niger at any concentration. Polyethylene samples with a 3% concentration demonstrated the greatest tensile strength in both the longitudinal and transverse directions. However, as the marjoram concentration increased, the elongation-at-break of the samples declined. Polyethylene films recorded the lowest elongation-at-break values at a 5% concentration in both directions. Water vapor permeability of the films also increased with marjoram powder concentration; it increased by 2.8 times at 3% compared to the control sample.
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- Pizzorni M, Innocenti A, Tollin N (2024) Droughts and floods in a changing climate and implications for multi-hazard urban planning: A review. City Environ Interact 24: 100169 [CrossRef]
- Pawase PA, Pathare AM, Bashir O, Saleem F, Shrama E, Mudgal S, Ahmad M (2025) Physical, chemical, and nano-enabled modifications of starch for sustainable food packaging films: recent trends, challenges, and prospects. Carbohydr Polym Technol Appl 11: 100986 [CrossRef]
- Onyeaka H, Ghosh S, Obileke K, Miri T, Odeyemi OA, Nwaiwu O, Tamasiga P (2024) Preventing chemical contaminants in food: Challenges and prospects for safe and sustainable food production. Food Control 155: 110040 [CrossRef]
- Deans SG, Svoboda KP (1990) The antimicrobial properties of marjoram (Origanum majorana L.) volatile o Flavour Fragr J 5: 187-190 [CrossRef]
- Kara M (2024) Determination of chemical compositions of rosemary and sweet marjoram essential oils and their blends and their antifungal potential against potato rubbery rot disease agent Geotrichum candidum. Plant Pathol J 106: 1173-1186 [CrossRef]
- Mazza KEL, Costa AMM, da Silva JPL, Alviano DS, Bizzo HR, Tonon RV (2023) Microencapsulation of marjoram essential oil as a food additive using sodium alginate and whey protein isolate. Int J Biol Macromol 233: 123478 [CrossRef]
- Güvensen NC, Keskin D (2021) Statistical determination of in-vitro antimicrobial effects of extracts of marjoram (Origanum majorana L.) from Muğla, Turkey. Int J Agric Food Sci 5: 398-404 [CrossRef]
- Kozłowska M, Laudy AE, Starościak BJ, Napiórkowski A, Chomicz L, Kazimierczuk Z (2010) Antimicrobial and antiprotozoal effect of sweet marjoram (Origanum majorana L.). Acta Sci Pol, Hortorum Cultus 9:133-141
- Almasi H, Azizi S, Amjadi S (2020) Development and characterization of pectin films activated by nanoemulsion and Pickering emulsion stabilized marjoram (Origanum majorana L.) essential oil. Food Hydrocoll 99: 105338 [CrossRef]
- Tamer TM, Alsehli MH, Omer AM, Afifi TH, Sabet MM, Mohy-Eldin MS, Hassan MA (2021) Development of polyvinyl alcohol/kaolin sponges stimulated by marjoram as hemostatic, antibacterial, and antioxidant dressings for wound healing p Int J Mol Sci 22: 13050 [CrossRef]
- Duong TH, Dinh KB, Luu T, Chapman J, Baji A, Truong VK (2024) Nanoengineered sustainable antimicrobial packaging: integrating essential oils into polymer matrices to combat food waste. Int J Food Sci Technol 59: 5887-5901 [CrossRef]
- Sardar NR, Akbari SH, Modi RB, Tawari M, Tagalpallewar GP (2024) Application of essential oils in food packaging: A concise review. European J Nutr Food Saf 16: 60-67 [CrossRef]
- Olewnik-Kruszkowska E, Vishwakarma A, Wrona M, Bertella A, Rudawska A, Gierszewska M, Schmidt B (2025) Comparative study of crucial properties of packaging based on polylactide and selected essential o Foods 14: 204 [CrossRef]
- Tomić A, Šovljanski O, Erceg T (2023) Insight on incorporation of essential oils as antimicrobial substances in biopolymer-based active p Antibiotics 12: 1473 [CrossRef]
- Zubair M, Shahzad S, Hussain A, Pradhan RA, Arshad M, Ullah A (2022) Current trends in the utilization of essential oils for polysaccharide- and protein-derived food packaging materials. Polymers 14: 1146 [CrossRef]
- Kola V, Carvalho IS (2023) Plant extracts as additives in biodegradable films and coatings in active food packaging. Food Biosci 54: 102860 [CrossRef]
- Bas-Bellver C, Barrera C, Betoret N, Seguí L (2022) Impact of disruption and drying conditions on physicochemical, functional and antioxidant properties of powdered ingredients obtained from brassica vegetable by-p Foods 11: 3663 [CrossRef]
- Kucharska-Guzik A, Guzik Ł, Charzyńska A, Michalska-Ciechanowska A (2025) Influence of freeze drying and spray drying on the physical and chemical properties of powders from Cistus creticus L. e Foods 14: 849 [CrossRef]
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