Nanotechnology has shown many advantages in different fields. As the uses of nanotechnology have progressed, it has been found to be a promising technology for the food packaging industry in the global market. It has proven capabilities that are valuable in packaging foods, including improved barriers; mechanical, thermal, and biodegradable properties; and applications in active and intelligent food packaging. Examples of the latter are anti-microbial agents and nanosensors, respectively. However, the use of nanocomposites in food packaging might be challenging due to the reduced particle size of nanomaterials and the fact that the chemical and physical characteristics of such tiny materials may be quite different from those of their macro-scale counterparts. In order to discuss the potential risks of nanoparticles for consumers, in addition to the quantification of data, a thorough investigation of their characteristics is required. Migration studies must be conducted to determine the amounts of nanomaterials released into the food matrices. In this article, different applications of nanocomposites in food packaging, migration issues, analyzing techniques, and the main concerns about their usage are discussed briefly.
In the present study, Lactobacillus acidophilus LA-5 was microencapsulated in sodium alginate, followed by fish gelatin coating (0.5, 1.5, and 3%). The survival of L. acidophilus in bread before and after encapsulation in alginate/fish gelatin during the baking and 7-day storage was investigated. Moreover, the effect of alginate/fish gelatin-encapsulated L. acidophilus on the technological properties of bread (hardness, staling rate, water content, oven spring, specific volume, and internal texture structure) was evaluated. Compared with control (free bacteria), encapsulated L. acidophilus in alginate/fish gelatin showed an increase in the viability of bread until 2.49 and 3.07 log CFU/g during baking and storage, respectively. Good viability of (106 CFU/g) for probiotic in encapsulated L. acidophilus in alginate/fish gelatin (1.5 and 3%, respectively) after 4-day storage was achieved. Fish gelatin as a second-layer carrier of the bacteria had a positive effect on improving the technical quality of bread. Furthermore, the staling rate of bread containing encapsulated L. acidophilus alginate/fish gelatin 0.5, 1.5, and 3% decreased by 19.5, 25.8, and 31.7%, respectively. Overall, the findings suggested encapsulation of L. acidophilus in alginate/fish gelatin capsule had great potential to improve probiotic bacteria’s survival during baking and storage and to serve as an effective bread enhancer.
Currently, bioactive compounds are required in the design and production of functional foods, with the aim of improving the health status of consumers all around the world. Various epidemiological and clinical studies have demonstrated the salutary role of eicosapentaenoic acid (EPA, 22:6 n−3) and docosahexaenoic acid (DHA, 22:5 n−3) in preventing diseases and reducing mortality from cardiovascular diseases. The unsaturated nature of bioactive lipids leads to susceptibility to oxidation under environmental conditions. Oxidative deterioration of omega-3 fatty acids can cause the reduction in their nutritional quality and sensory properties. Encapsulation of these fatty acids could create a barrier against reaction with harmful environmental factors. Currently, fortification of foods containing bioactive omega-3 fatty acids has found great application in the food industries of different countries. Previous studies have suggested that nano-encapsulation has significant effects on the stability of physical and chemical properties of bioactive compounds. Considering the functional role of omega-3 fatty acids, this study has provided a literature review on applications of nanoliposomal delivery systems for encapsulation of these bioactive compounds.
Introduction: Mycotoxin producing fungi are major contributors to food contamination and many epidemics in humans and animals. The adverse effects of the use of chemical preservatives have led to a special focus on the use of natural compounds, especially plant derivatives. The aim of this study was to investigate the antifungal properties of herbal essential oils of Cinnamon, Clove, Thymes, and Zataria multiflora, Cumin, and Caraway on the growth of Aspergillus ochraceus.
Materials and Methods: Briefly, the presence of mycotoxin producing gene was investigated using PCR. Furthermore, production of mycotoxin in a medium with high performance liquid chromatography with fluorescence detection (FLD) was evaluated. Ingredients of essential oils were determined using GC/MS. The amount of antifungal activity of essential oils was assessed by disc diffusion and well diffusion method. Additionally, the minimum inhibitory concentration (MIC) was determined by macrodilution method.
Results: Gene presence and mycotoxin production were confirmed by PCR and HPLC-FL. Among all studied essential oils, Cinnamon with MIC and MFC of 0.078 μl / ml exhibited the greatest effect on A. ochraceus growth as compared to other essential oils.
Conclusion: This study indicated that essential oils have an effective role on controlling A. ochraceus growth and have shown promising to be a good bioactive natural preservative in food industry.
This study aimed to develop a nanoliposomal formulation containing a-tocopherol loaded with eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA) and to characterise the formulation by its physical stability. For this purpose, different nanoliposomal formulations with dipalmitoyl phosphocholine were prepared using a modified thin-film hydration method and evaluated by particle size, polydispersity index (PDI), transmission electron microscopy, differential scanning calorimetry and determining the encapsulation efficiencies of DHA and EPA. A physical stability study was conducted by investigating the change in the vesicle encapsulation efficiency, particle size, PDI and shape when stored at 4, 30 and 40°C for 3 months. High encapsulation efficiency of DHA and EPA (89.1% AE 0.6% and 81.9% AE 1.4%) and appropriate particle size (82 AE 0.8 nm) were obtained for liposomes composed of a-tocopherol. The optimum formulation was stable for 90 days when kept at 4°C. This study demonstrated that a-tocopherol had a protective effect on the physical stability of the nanoliposomes containing DHA and EPA.
Background: Geraniol (GE), as secondary metabolites of plant and natural bioactive essential oils is one of the major compounds of Rosa damascena Mill and widely used as fragrance/flavor in the food industry. Rosa damascena Mill and geraniol have numerous health benefits for human consumption. Currently, there is no single article that extensively covers the complete range of beneficial effects of GE that could improve knowledge in this category. Objective: The purpose of this study was to provide a comprehensive review of all published specific articles about beneficial properties of GE, as a monoterpene component of medicinal plants. Methods: Data were selected from Scopus, Clarivate Web Of Science TM , Embase, ScienceDirect and PubMed databases from 1940-2019 by identifying keywords and creating complex searches. Results: Based on the search results, GE identified as a natural compound having insecticidal and repellent activities. GE introduces a new class of cancer chemopreventive agents due to its citronellol and trans-geraniol.Other functional properties such as antibacterial, antifungal, antioxidant and anti-inflammatory of GE have also been found. Conclusion: Overall, this approach has been a systematic literature review to provide an effective strategy for rapidly evaluating research results. This study suggests that the GE and Rosa damascena Mill have multiple health benefits and they are recommended for their therapeutic effects.
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