Nanotechnology-Enhanced Food Packaging. Группа авторов. Читать онлайн. Newlib. NEWLIB.NET

Автор: Группа авторов
Издательство: John Wiley & Sons Limited
Серия:
Жанр произведения: Техническая литература
Год издания: 0
isbn: 9783527827725
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for good antibacterial activity at low concentrations and increased stability under intense conditions [27]. The use of these nanoparticles in antimicrobial food packaging was therefore very important in recent years.

Schematic illustration of features of food nano-packaging applied in the food industry.

      Antimicrobial packaging is not limited to antimicrobial products, but nano-compositions and nanolaminates are widely used in product packaging to resist intense mechanical and thermal shocks, which increase food shelf life. The incorporation of nanoparticles into packaging materials provides quality foods with longer durability. Moreover, to ensure the highest food-grading quality and standard, polymer composites are designed to supply both thermostable and usable packaging materials. Numerous inorganic or organic fillers are used to produce better polymer composites. The addition of nanoparticles in polymers has made it possible to develop robust, cost-effective packaging material.

      1.4.1 Usages of Nanosensors in Pathogen and Adulterant Detection in the Food Industry

      Nanomaterials for use in the development of biosensors include high responsiveness and other modern features. In dietary microbiology, nanosensors or nanobiosensors are used to detect pathogens in processing plants and foodstuffs, to measure accessible foodstuffs, and to alert customers and suppliers to food health. The nanosensor serves as an indicator of changes in environmental conditions, such as humidity or storage temperature, microbial contamination, or product degradation. To achieve potential biosensor applications, former researchers have studied specific nanostructures such as thin films, nanoparticles, nanorods, and nanofibers. These thin, film-based optical immunosensors have contributed to efficient and highly responsive detection systems for microbial or cell detection. These immunosensors are used to immobilize specific anticorps, antigens, or protein molecules on thin nanofilms or sensor chips that transmit signals for the detection of target molecules. Dimethyl siloxane combined with carbohydrate biosensors has been very carefully identified and used for microorganisms, contaminants, and other food and beverage-related items due to their quick identification, usability and cost-effectiveness. The contaminants connected to such nanotubes induce observable shifts of conductivity of waterborne contaminants in the identification of waterborne toxins. Therefore, the use of an electronic nose or tongue consisting of several nanosensors tracks food by communicating scents of foodstuffs or gas signals [28–30].

      Adulteration is one of the key challenges faced in the food sector. Nanosensors have better sensitivity and accuracy than other sensors, for example, gold nanoparticles functionalized with cyanuric acid groups selectively bind to melamine, a common adulterant used to inflate the protein content in pet foods and infant formulas. Similarly, melamine adulteration in raw milk can also be detected up to 2.5 ppb using nanosensors.

      1.4.2 Nanotechnology Applications in Food Safety Issues

Schematic illustration of diverse applications of nanotechnology in the food industry.

      1.4.3 Bio-Based Nano-packaging in Food Industry

      The promising design of bio-based nanocomposites for synthetic polymers drives new work on nanocomposites for use in food packaging. The classification of biopolymers is available in the literature. The use of nanotechnology on such polymers can offer new ways to improve both their properties and their cost-effectiveness. The most well-studied bionanocomposites are starch and derivatives such as polylactic acid (butylene succinate), polyhydroxybutyrate, and aliphatic polyester [35–38].

      The three main applications of nanomaterial in food packaging were further described as the research trends in food packaging using nanotechnology, where nanoreinforcement, active nanocomposite packaging, and smart nanocomposites are mainly involved in food packaging. In active packaging, the well-known ingredients of antimicrobial packaging are silver, gold, and metal oxide nanoparticles. Silver nanoparticles found in several commercial applications are most widely studied. It may also be suitable for other active packaging fields, such as ethylene removers [39–43]. Nanosensors can respond to external changes in stimuli. The latest developments in smart food packaging polymer nanomaterials include indicators of oxygen, freshness, and pathogens [44, 45]. EcoSphere Biolatex® is a novel technology developed by the EcoSynthetix company. It is a biopolymer nanosphere with a granule size of 50–150 nm and a higher surface area than native starch. It possesses high solid dispersion