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Nanotechnology-Enhanced Food Packaging


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behavior of ultraviolet nanocrystalline titania. Since TiO2 acts by a photocatalytic mechanism, the requirement for ultraviolet absorption (UVA) light is its major drawback [53].

      The film based on nanocrystalline titanium (TiO2) is the commonly used material for UV absorption. During the exposure to sunlight, the effectiveness of TiO2-coated film exposure to sunlight inactivates TiO2 visible photo- catalytic absorption in the context of UV irradiation. Doping TiO2 with silver has been reported to have greatly improved photocatalytic bacterial inactivation. The resulting combination was good antibacterial properties of nanoparticles TiO2/Ag+ in a polyvinyl chloride (PVC) nanocomposite.

      The chemical interactions of nanosensors with spoilage components produced during the deterioration of food resulted in color change and state the level of freshness. The electrical, electronic, magnetic, and optical properties of polymers or electrically active conjugated polymers play an important role in chemical or electrical oxidation. Particularly electrochemical-polymerized conducting polymers may switch from oxidized (doped) to reduced (undoped) isolating state, which is the basis for many applications. The product indicator includes polyaniline film, which responds to several fundamental volatile amines released by noticeable colors during fish spoilage. Color variations were well linked in terms of overall volatile amine concentrations and microbial fish sample development rates in terms of the gross polyaniline (Milkfish) color variation [55].

      Intelligent package has the potential to improve food safety and reduce food bone illness. Food spoilage is induced by microorganisms whose metabolism creates volatile compounds that can be identified by the conduction and/or recognition of micro-orientations dependent on gas emissions and food-freshness detections through performing polymer nanocomposites or metal oxides. Polymer nanocomposite-based sensors are used to conduct particles that are integrated into the polymer insulation matrix. The sensor resistance changes establish a pattern that adapts to the studied material. Conducting polymer nanocomposite sensors in black and polyaniline carbon were designed for the detection and identification of foodborne pathogens by producing a specific response pattern for each microorganism (for example, Salmonella sp., Bacillus parahemolyticus). For example, chicken freshness was analyzed based on the fragrance using a neural network to analyze metallic performance results such as tin and indium oxide gas sensors. In food packaging, a device that has several nanosensors, which are extremely susceptible to spoilage markers, creates a color change that indicates when the food is harmed.

      Nanoparticles can be used as some smart food packaging as a food safety tracking device or to avoid falsification. BioMerieux has developed the Food Expert ID® multi detection test for nano-monitoring responses to food scares. Nanobarcodes for individual objects or pellets were produced by the US Oxonica Inc., which must be interpreted using a modified microscope for anti-counterfeiting purposes. Commercially available nanobars are made of inert metals, such as nickel, platinum gold, and silver, by electroplating into templates that define the particle diameter, which then releases stripped nanorods from templates [1–4].

      In the last ten years, nanotechnology offers enormous opportunities for creative food packaging technologies that favor customers and businesses alike. Even at an early stage of improvement of the material properties of packaging, nanotechnology will have significant advantages and will require continuing investments of nanotechnological applications in packaging materials. Nanotechnology may offer a range of advantages in the context of advanced functional properties to render food packaging. Nanotechnology can improve food safety, making it convenient and creating modern product processing and innovative product and storage functions. However, all technologies are still at an intermediate level, and most of them, at least in the short term, are looking for good quality products. Also, nanomaterials can be used for the production of packaging, which keeps the product fresher indoors for longer food life and improves food safety. Smart packaging with nanosensors can also provide customers with inside knowledge of the food condition. Sensors can warn or inform consumers of the exact nutritional status contained therein before the food is spoiled. Nanotechnology is transforming the production of the entire packaging company.

      1 1 Kuswandi, B. (2016). Nanotechnology in food packaging. In: Nanoscience in Food and Agriculture, Sustainable Agriculture Reviews 20, vol. 1 (eds. S. Ranjan et al.), 151–183. Cham: Springer https://doi.org/10.1007/978-3-319-39303-2_6.

      2 2 Kuswandi, B. (2017). Environmental friendly food nano-packaging. Environ. Chem. Lett. 15 (2): 205–221.

      3 3 Singh, T., Shukla, S., Kumar, P. et al. (2017). Application of nanotechnology in food science: perception and overview. Front. Microbiol. 8: 1501.

      4 4 Dasgupta, N., Ranjan, S., Mundekkad, D. et al. (2015). Nanotechnology in agrofood: from field to plate. Food