Natural antioxidants as strategy to minimize the presence of lipid oxidation products in canned fish: Research progress, current trends and future perspectives.

Canned fish is one of the most popular forms of fish consumption due to its high nutritional value, availability, and practicality. However, canning may induce lipid oxidation. Thus, this study provides in-depth information on the impact of high temperatures applied during canning on fish lipids. The thermo-oxidation is evidenced, for example, by the high levels of both primary and secondary oxidation products determined in fish after canning, as well as the presence of harmful compounds such as cholesterol oxides. Given the role of lipid oxidation in canned fish, this study also presents a comprehensive review on using natural antioxidants to control it. The antioxidant properties of common liquid mediums (vegetable oils and sauces) are highlighted. Moreover, adding algae extracts, spices, and condiments to the liquid medium to enhance its antioxidant potential has been considered, while the exploitation of by-products and wastes from the food industry also emerges as a suitable strategy. Besides the promising results, these practices may promote positive impacts on other quality parameters (e.g. water and oil holding capacities, texture, microbiological growth). However, further studies are needed, including research on aspects related to safety, effective concentrations and application methods, without ignoring consumers' sensory acceptance.

Effect of aroeira (Schinus terebinthifolius Raddi) fruit against polyunsaturated fatty acids and cholesterol thermo-oxidation in model systems containing sardine oil (Sardinella brasiliensis).

This study evaluated the protective effect of ground aroeira (Schinus terebinthifolius Raddi) fruit addition against fatty acids and cholesterol oxidation in model systems containing sardine oil (Sardinella brasiliensis) during heating (150 and 180 °C). High temperatures reduced the amount of essential polyunsaturated fatty acids and caused the formation of oxidized products. Total cholesterol oxides content increased from 58.9 ± 0.26 to 577.5 ± 2.14 µg/g oil, after heating at 180 °C. However, aroeira significantly protected lipids from oxidation. Although the synthetic antioxidant applied as standard (butylated hydroxytoluene) showed greater results, it was used in the maximum concentration permitted by Brazilian legislation (0.01%), suggesting that aroeira fruit could be used as a natural antioxidant for the food industry. The protective effect of aroeira may be correlated to its antioxidant capacity and the presence of bioactive compounds which were identified by UHPLC-ESI-MS in the aroeira extract.

Use of Natural Antioxidants in the Inhibition of Cholesterol Oxidation: A Review.

Synthetic antioxidants are widely used in the food industry. However, the potential toxicity, carcinogenic effects, and possible health damage caused by the ingestion of synthetic compounds, and also consumer concern about the safety of such additives has motivated the food industry to search for natural alternatives. Natural compounds with antioxidant properties are able to retard or prevent lipid oxidation in food. Animal sources like fish, eggs, meats, and dairy products are essential foods for human health due to their lipid fraction with high contents of unsaturated compounds, such as polyunsaturated fatty acids and cholesterol. However, these unsaturated lipids when exposed to favorable factors can become oxidized, which leads to sensory and nutritional losses as well as the formation of oxidized compounds known as cholesterol oxidation products or COPs. COPs are associated with deleterious health effects, such as inflammation, cytotoxicity, atherogenesis, carcinogenesis, and alterations in cell membrane properties, as well as the development of degenerative diseases such as Alzheimer's, Parkinson's, Huntington's, and other chronic diseases. Thus, the use of natural antioxidants can be an alternative to synthetics to prevent the formation of COPs and extend the shelf life of foods susceptible to oxidative deterioration. This review brings together information concerning the use of natural antioxidants as a strategy to control cholesterol oxidation.

Microencapsulation of sacha inchi oil using emulsion-based delivery systems.

In this study, sacha inchi oil (SIO) was microencapsulated by emulsion-based systems using ovalbumin (Ova), pectin (Pec), and xanthan gum (XG), followed by freeze-drying. The microencapsulation was confirmed using Fourier transform infrared (FTIR) spectroscopy, X-ray diffraction (XRD), thermogravimetric analysis (TGA), and scanning electron microscopy (SEM). The stability of omega-3 in SIO alone as well as in microencapsulated SIO was assessed by nuclear magnetic resonance (1H NMR) spectroscopy after human gastric simulation (HGS). The SEM results revealed distinct structures for the two types of microcapsules. The thermograms showed that the thermal resistance was increased in the microencapsulated SIO, indicating that the emulsion-based system may be a way to protect the omega-3 in the SIO. In addition, the microencapsulation conferred an increased crystallinity degree, indicating a higher structural organization. Moreover, this method did not affect the stability of SIO, as confirmed by 1H NMR. The release of omega-3 acyl units from the SIO was correlated with the decrease of the methynic proton (sn, 2 position) of triacylglycerol (TAG). In contrast, the increase of 1,3-diglycerides was negatively correlated with the decrease of glyceryl groups (sn, 1,3 positions). The HGS conditions did not significantly alter the stability of the omega-3 of SIO over 180min. The SIO-Ova microcapsules had a similar behavior to the SIO, and the presence of Ova was not enough to prevent the decrease of omega-3 content over 180min. The SIO-Ova-Pec and SIO-Ova-XG microcapsules were shown to protect the omega-3 content effectively. In conclusion, the microcapsules developed in this study can be used to transport nutraceutical compounds because they are resistant to the human gastric conditions tested in vitro.