Utilizing Food Waste for Sustainable Packaging: A Biodegradable Approach to Replacing Plastic
DOI:
https://doi.org/10.54536/ijsa.v3i1.3814Keywords:
Biodegradable Packaging, Biofilms, Cardboard, Eco-Friendly, Foams, Food Waste, Kraft Paper, Mushroom, Plastic PackagingAbstract
Plastic is harmful to human health and is not an environmentally friendly product. Over thousands of years, plastic does not degrade or decompose. Food waste has been used for years to replace plastic or plastic derivatives or create eco-friendly biodegradable packaging material. Packaging is vital for product protection and has a high value at all stages. Different materials have been introduced to replace plastic. This article discussed the use of various food waste to replace specific plastic packaging materials. A commonly accepted strategy for building a sustainable society is to use waste biomass such as fiber, cellulose, and starch to substitute petrochemical ingredients in manufacturing plastics. Bioplastics or biodegradable polymers are plastics manufactured from biomass. Mushroom waste has been used to make an alternative to Styrofoam, Mushroom pulp or fiber utilization for the development of Kraft paper packaging has shown to be the best alternative, as it has high mechanical strength, and it is biodegradable, organic, or non-hazardous to humans. Similarly, cucumber peel was used to make biodegradable packaging films that act as an oxygen barrier in the atmosphere. Cucumber peels can be employed as Nano-fillers in bio-composite film, resulting in effective food packaging materials with low ionic conductivity. Sugar cane bagasse is also an excellent alternative to plastic film packaging. Since agricultural wastes may be turned into new value-added commodities, sugarcane bagasse waste could contribute to societal economic success while fostering a green environment. Garlic peels are also being used to create paper packaging. Garlic peel-based biodegradable packs were evaluated and confirmed to be suitable for usage as carry bags or pouches. Foams, Kraft sheets, and Biofilms are used to protect fruits and vegetables, as well as beans, cereal, grains, and other food goods. However, these food waste materials can be used to produce biodegradable packaging material as an alternative to hazardous plastic.
References
Aamir, M., Ahmad, H., Javaid, Q., & Hasan, S. M. (2018). Waste not, want not: a case study on food waste in restaurants of Lahore, Pakistan. Journal of Food Products Marketing, 24(5), 591-610.
Abhijith, R., Ashok, A., & Rejeesh, C. (2018). Sustainable packaging applications from mycelium to substitute polystyrene: a review. Materials today: proceedings, 5(1), 2139-2145.
Ajala, E., Ighalo, J., Ajala, M., Adeniyi, A., & Ayanshola, A. (2021). Sugarcane bagasse: a biomass sufficiently applied for improving global energy, environment and economic sustainability. Bioresources and Bioprocessing, 8, 1-25.
Alabi, O. A., Ologbonjaye, K. I., Awosolu, O., & Alalade, O. E. (2019). Public and environmental health effects of plastic waste disposal: A review. Journal of Toxicology and Risk Assessment, 5(021), 1-13.
Alexander, C., Gregson, N., & Gille, Z. (2013). Food waste. In The handbook of food research (Vol. 1, pp. 471-483). Routledge.
Amasuomo, E., & Baird, J. (2016). The concept of waste and waste management. Journal of Management & Sustainability, 6(2), 88.
Angelova, G. V., Brazkova, M. S., & Krastanov, A. I. (2021). Renewable mycelium-based composite: A sustainable approach for lignocellulose waste recovery and an alternative to synthetic materials—A review. Zeitschrift für Naturforschung C, 76(11-12), 431-442.
Antunes, F., Marçal, S., Taofiq, O., Morais, A. M. M. B., Freitas, A. C., Ferreira, I. C. F. R., & Pintado, M. (2020). Valorization of mushroom by-products as a source of value-added compounds and potential applications. Molecules, 25(11), 2672.
Azmin, S. N. H. M., & Nor, M. S. M. (2020). Development and characterization of food packaging bioplastic film from cocoa pod husk cellulose incorporated with sugarcane bagasse fiber. Journal of Bioresources and Bioproducts, 5(4), 248-255.
Bordonal, R. d. O., Carvalho, J. L. N., Lal, R., De Figueiredo, E. B., De Oliveira, B. G., & La Scala, N. (2018). Sustainability of sugarcane production in Brazil. A review. Agronomy for Sustainable Development, 38, 1-23.
Boyaci, D., Onarinde, B., Aiyedun, S., Waldron, K. W., May, D., & Tucker, N. (2022). The beneficial effects of the addition of pulped Agaricus bisporus mushroom body co-product to Kraft pulp packaging materials. Cleaner Materials, 3, 100049.
Chaudhary, B. U., Lingayat, S., Banerjee, A. N., & Kale, R. D. (2021). Development of multifunctional food packaging films based on waste Garlic peel extract and Chitosan. International Journal of Biological Macromolecules, 192, 479-490.
Chohan, M. (2019). Impact of climate change on sugarcane crop and remedial measures-a review. Pakistan Sugar Journal, 34(1), 15-22.
Correa-Cano, M. E., Burton, K., Mueller, M., Kouloumpis, V., & Yan, X. (2023). Quantification of Plastics in Agriculture and Fisheries at a Regional Scale: A Case Study of South West England. Recycling, 8(6), 99.
Coultate, T. (2023). Food: The chemistry of its components. Royal Society of Chemistry.
Deshwal, G. K., Panjagari, N. R., & Alam, T. (2019). An overview of paper and paper-based food packaging materials: Health safety and environmental concerns. Journal of Food Science and Technology, 56, 4391-4403.
Flack‐Prain, S., Shi, L., Zhu, P., da Rocha, H. R., Cabral, O., Hu, S., & Williams, M. (2021). The impact of climate change and climate extremes on sugarcane production. GCB Bioenergy, 13(3), 408-424.
Garcia-Garcia, G., Woolley, E., & Rahimifard, S. (2015). A framework for a more efficient approach to food waste management. International Journal of Food Engineering, 1(1), 65-72.
Guo, J., Zhang, M., & Fang, Z. (2022). Valorization of mushroom by‐products: a review. Journal of the Science of Food and Agriculture, 102(13), 5593-5605.
Gupta, R. K., Ali, E. A., Abd El Gawad, F., Daood, V. M., Sabry, H., Karunanithi, S., & Srivastav, P. P. (2024). Valorization of fruits and vegetable waste byproducts for the development of sustainable food packaging applications. Waste Management Bulletin.
Ho, B. T., Roberts, T. K., & Lucas, S. (2018). An overview on biodegradation of polystyrene and modified polystyrene: The microbial approach. Critical Reviews in Biotechnology, 38(2), 308-320.
Hussain, N., Ali, S., Miraj, N., & Sajjad, M. (2014). An estimation of technical efficiency of garlic production in Khyber Pakhtunkhwa Pakistan. International Journal of Food and Agricultural Economics (IJFAEC), 2(2), 169-178.
Irimia, A., & Popescu, C.-M. (2023). Bioactive paper packaging for extended food shelf life. Coatings, 13(9), 1658.
Ishangulyyev, R., Kim, S., & Lee, S. H. (2019). Understanding food loss and waste—Why are we losing and wasting food? Foods, 8(8), 297.
Joardder, M. U., Masud, M. H., Joardder, M. U., & Masud, M. H. (2019). Causes of food waste. In Food preservation in developing countries: Challenges and solutions (pp. 27-55). Springer.
Jose, J., Uvais, K., Sreenadh, T., Deepak, A. V., & Rejeesh, C. (2021). Investigations into the development of a mycelium biocomposite to substitute polystyrene in packaging applications. Arabian Journal for Science and Engineering, 46, 2975-2984.
Kannah, R. Y., Merrylin, J., Devi, T. P., Kavitha, S., Sivashanmugam, P., Kumar, G., & Banu, J. R. (2020). Food waste valorization: Biofuels and value added product recovery. Bioresource Technology Reports, 11, 100524.
Khan, H., Lee, R., & Lockshin, L. (2015). Localising the packaging of foreign food brands: a case of Muslim consumers in Pakistan. Journal of Product & Brand Management, 24(4), 386-398.
Khan, M. R., Sadiq, M. B., Vápenka, L., Volpe, S., Rajchl, A., & Torrieri, E. (2024). Role of quality assessment of the recycled packaging material in determining its safety profile as food contact material. Waste Management, 188, 72-85.
Kim, Y., & Ruedy, D. R. (2023). Mushroom packages: an ecovative approach in packaging industry. In Sustainable Development and Environmental Stewardship: Global Initiatives Towards Engaged Sustainability (pp. 199-223). Springer.
Kimura, S., Tung, Y. C., Pan, M. H., Su, N. W., Lai, Y. J., & Cheng, K. C. (2017). Black garlic: A critical review of its production, bioactivity, and application. Journal of Food and Drug Analysis, 25(1), 62-70.
Kozlowski, M. (2015). Recycling of Food Packaging Materials. Functional Polymers in Food Science: From Technology to Biology, 1, 355-399.
Krivanek, S. (2020). Fungal mycelium: The key to a sustainable future.
Kumar, H., Bhardwaj, K., Sharma, R., Nepovimova, E., Cruz-Martins, N., Dhanjal, D. S., Singh, R., Chopra, C., Verma, R., & Abd-Elsalam, K. A. (2021). Potential usage of edible mushrooms and their residues to retrieve valuable supplies for industrial applications. Journal of Fungi, 7(6), 427.
Kumar, K., Mehra, R., Guiné, R. P., Lima, M. J., Kumar, N., Kaushik, R., Ahmed, N., Yadav, A. N., & Kumar, H. (2021). Edible mushrooms: A comprehensive review on bioactive compounds with health benefits and processing aspects. Foods, 10(12), 2996.
Lickly, T., Lehr, K., & Welsh, G. (1995). Migration of styrene from polystyrene foam food-contact articles. Food and Chemical Toxicology, 33(6), 475-481.
Lim, Y., Izhar, T., Zakarya, I., Yusuf, S., Zaaba, S., & Mohamad, M. (2021). Life cycle assessment of expanded polystyrene. IOP Conference Series: Earth and Environmental Science, 763, 012080.
Loh, Y., Sujan, D., Rahman, M. E., & Das, C. A. (2013). Sugarcane bagasse—The future composite material: A literature review. Resources, Conservation and Recycling, 75, 14-22.
Majib, N. M., Sam, S. T., Yaacob, N. D., Rohaizad, N. M., & Tan, W. K. (2023). Characterization of fungal foams from edible mushrooms using different agricultural wastes as substrates for packaging material. Polymers, 15(4), 873.
Mallick, P. K. (2022). Evaluating potential importance of cucumber (Cucumis sativus L.-Cucurbitaceae): A brief review.
Melguizo-Rodríguez, L., García-Recio, E., Ruiz, C., De Luna-Bertos, E., Illescas-Montes, R., & Costela-Ruiz, V. J. (2022). Biological properties and therapeutic applications of garlic and its components. Food & Function, 13(5), 2415-2426.
Mojumdar, A., Behera, H. T., & Ray, L. (2021). Mushroom mycelia-based material: An environmentally friendly alternative to synthetic packaging. In Microbial polymers: Applications and ecological perspectives (pp. 131-141). Springer.
Motaung, T. E., & Mochane, M. J. (2018). Systematic review on recent studies on sugar cane bagasse and bagasse cellulose polymer composites. Journal of Thermoplastic Composite Materials, 31(10), 1416-1432.
Muthukumar, J., Kandukuri, V. A., & Chidambaram, R. (2024). A critical review on various treatment, conversion, and disposal approaches of commonly used polystyrene. Polymer Bulletin, 81(4), 2819-2845.
Nadeem, H., & Muneer, F. (2021). Plastics Versus Bioplastics. Materials Research Foundations, 99.
Ncube, L. K., Ude, A. U., Ogunmuyiwa, E. N., Zulkifli, R., & Beas, I. N. (2021). An overview of plastic waste generation and management in food packaging industries. Recycling, 6(1), 12.
Nigam, R., & Sharma, S. (2017). Food waste management. Amity Journal of Energy & Environment Studies, 3, 1-8.
Nurmalina, R., & Agustian, A. (2023). Assessing the sustainability of garlic production for determining strategies in the Garlic Sustainable Development Program. IOP Conference Series: Earth and Environmental Science, 1082, 012032.
Okuda, Y. (2022). Sustainability perspectives for future continuity of mushroom production: The bright and dark sides. Frontiers in Sustainable Food Systems, 6, 1026508.
Pohan, J. N., Kusumawati, Y. A., & Radhitanti, A. (2023). Mushroom mycelium-based biodegradable packaging material: A promising sustainable solution for the food industry. E3S Web of Conferences, 385, 01005.
Prasanna, N. S. (n.d.). Scope of cellulose nanotechnology in biodegradable food packaging. In I. D. Healey (Ed.), Cellulose nanotechnology (p. 30). Springer.
Prasanna, N. S., & Mitra, J. (2020). Isolation and characterization of cellulose nanocrystals from Cucumis sativus peels. Carbohydrate Polymers, 247, 116706.
Qamar, A., Ashfaq, M., & Khan, M. (2017). Resource use efficiency and return to scale analysis in off-season cucumber production in Punjab, Pakistan. Sarhad Journal of Agriculture, 33(1), 47-52.
Saif, S., Hanif, M. A., Rehman, R., & Riaz, M. (2020). Garlic. In Medicinal plants of South Asia (pp. 301-315). Elsevier.
Samarasekara, A., Somasuntharam, P., & Umadaran, S. (2015). Development of environmentally friendly cellulose-containing packaging products from waste materials.
Shekhar, S. K., & Raveendran, P. (2017). Perceptions and attitudes towards the silent salesman. International Journal of Business Innovation and Research, 14(1), 104-121.
Singh, A., Singhania, R. R., Soam, S., Chen, C. W., Haldar, D., Varjani, S., Chang, J. S., Dong, C. D., & Patel, A. K. (2022). Production of bioethanol from food waste: Status and perspectives. Bioresource Technology, 360, 127651.
Singh, A. K., Itkor, P., Lee, M., Shin, J., & Lee, Y. S. (2023). Promoting sustainable packaging applications in the circular economy by exploring and advancing molded pulp materials for food products: A review. Critical Reviews in Food Science and Nutrition, 63(32), 11010-11025.
Srivastava, S., Sharma, U., Singh, B., & Yadava, H. (2012). A profile of garlic production in India: facts, trends and opportunities. International Journal of Agriculture, Environment and Biotechnology, 5(4), 477-482.
Steenis, N. D. (2019). Consumer response to sustainable packaging design [Doctoral dissertation, Wageningen University and Research]. Wageningen University & Research Repository.
Thompsett, D. (2013). Polystyrene. In Construction materials reference book (pp. 249-267). Elsevier.
Trache, D., Hussin, M. H., Haafiz, M. M., & Thakur, V. K. (2017). Recent progress in cellulose nanocrystals: sources and production. Nanoscale, 9(5), 1763-1786.
Vasquez, E. S. L., & Vega, K. (2019). Myco-accessories: Sustainable wearables with biodegradable materials. In Proceedings of the 2019 ACM International Symposium on Wearable Computers (pp. 135-142).
Wirth, H. (1967). New applications for polystyrene foam. Journal of Cellular Plastics, 3(10), 463-467.
Zhao, D., & Li, Y. R. (2015). Climate change and sugarcane production: potential impact and mitigation strategies. International Journal of Agronomy, 2015(1), 547386.
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