Application of chickpea-based edible coating with chickpea husk polyphenols on the preservation of sunflower seeds.

The objective of this study was to evaluate the protective effect of a chickpea-based edible coating with the addition of polyphenols on the chemical, microbiological, and sensory quality of roasted sunflower seeds throughout storage. Four different samples were prepared: roasted sunflower seeds (control sample, SF-C), roasted sunflower seeds with BHT (SF-BHT), roasted sunflower seeds with chickpea-based coating (SF-CCs), and roasted sunflower seeds with chickpea-based coating with chickpea polyphenolic extract (SF-CCPE). The samples were stored for 60 days at room temperature, and their chemical, microbiological, and sensory parameters were analyzed. The acceptability of fresh samples was also studied. The use of chickpea-based coatings retarded the lipid oxidation process efficiently, but the inclusion of chickpea polyphenols in the coating enhanced the protective effect. At 60th day of storage, no statistically significant differences were found between SF-CCPE and SF-BHT in relation to peroxides and conjugated dienes values, saturated/unsaturated ratio, and hexanal content. Linoleic acid content was reduced significantly more in SF-CCs than SF-CCPE. The addition of chickpea coating with chickpea antioxidants did not modify the flavor of the sunflower seeds and was the most accepted treatment by the consumer. The formation of undesirable flavors (cardboard and oxidized) was less in SF-CC, SF-CCPE, and SF-BHT without finding significant differences between these treatments. None of the samples presented microbiological contamination or an increase in bacteria, yeast, and molds during storage. The chickpea-based coating was able to retard lipid oxidation in roasted sunflower seeds, proving to be a good alternative as a natural method to preserve foods with high lipid content. PRACTICAL APPLICATION: Discarded chickpeas and chickpea husks constitute byproducts from the chickpea industry. The grain husks are currently discarded or marketed at a very low cost, constituting a novel residue with antioxidant properties. Considering the growing interest in sustainability and the circular economy, this investigation proposes the utilization of nutritional materials to prepare edible coatings. The chickpea-based coatings loaded with polyphenol extract (obtained from the husk of chickpea) demonstrated to have a protective effect against lipid oxidation process in sunflower seeds, which represent a good alternative to be used for the food industry to increase the shelf life of lipid foods.

Sunflower oil preservation by using chickpea flour film as bio-packaging material.

The aim of this study was to evaluate the protective effect of biodegradable packages made with chickpea flour on the oxidation of sunflower oil. Chickpea flour films were prepared using the casting technique. To study the influence of storage time on films properties, the chickpea flour films were stored during 60 days at 25 °C and 52% relative humidity. In addition, sunflower oil samples were packaged in chickpea flour packages (CPs) and stored for 60 days at 25 °C. Lipid oxidation indicators were evaluated. The results showed that puncture force and redness values (a*) of chickpea films did not change significantly during storage. Tensile strength, Young's modulus (YM), and yellowness (b*) increased and moisture content (MC), elongation (%E), solubility (%S), water vapor permeability (WVP), and luminosity (L*) decreased. Microscopic images showed the presence of a few cracks in the film network at storage day 60. Conjugated dienes and peroxide value increased less for sunflower oil stored in high-barrier plastic pouches and CPs during storage than the control treatment. CPs helped to preserve the chemical quality of sunflower oil samples, proving to be a promising alternative to develop biodegradable packaging to be used in oily food preservation. PRACTICAL APPLICATION: Discarded chickpea grains are those split and different color grains that are separated from marketable grains, and represent an industrial byproduct. These grains are currently used for feed, constituting a nutritive biomass of low commercial value. Chickpea flour is a potential material for making biodegradable films. This strategy allows adding value to the chickpea industry, transforming a byproduct into a raw material with the potential to develop economical food packaging material. The use of chickpea packages to preserve sunflower oil may be an alternative to pack vegetable oil or high lipid content food, allowing the use reduction of nonbiodegradable pouches.

Improving walnuts' preservation by using walnut phenolic extracts as natural antioxidants through a walnut protein-based edible coating.

Walnut kernels contain high amounts of polyunsaturated fatty acids that determine a limited shelf life on these nuts. The application of walnut phenolics as antioxidants through a walnut protein-based coating, obtained from walnut oil cake residue, can help to increase the shelf life of walnuts. The objective was to evaluate the preservative effect of walnut polyphenols included in a walnut-proteic edible coating on walnut kernels. Three treatments of walnuts coated with walnut flour were prepared: without the addition of antioxidants (control); with the addition of a walnut phenolic extract; and with the addition of butylated hydroxytoluene (BHT). On the last storage day, the sample with the addition of walnut phenolics presented a lower peroxide (3.64 meq 02 /kg oil) and anisidine value (1.11), conjugated diene (15.92), and hexanal content (19.67 × 106 e.c.) than the control sample (6.23, 1.81, 24.65, and 122.37 × 106 e.c., respectively). Also, on the last day, the control sample showed the highest deterioration of polyunsaturated fatty acids (from 74.83 to 71.08 g/100g), carotenoid (from 3.43 to 1.90 mg/kg), and γ-tocopherol content (from 349.66 to 298.42 mg/kg). In addition, this sample exhibited the highest oxidized (20.33) and the lowest walnut flavor intensity (64.67) on day 84. Regarding consumer acceptance, the phenolic-added sample displayed a greater flavor acceptance score. Walnut phenolics, implemented through a walnut protein-based coating, improve the preservation of walnuts. PRACTICAL APPLICATION: The combination of walnut-phenolic extracts and walnut-based edible coating applied on walnuts by food industries allows to prolong their shelf life, by preserving their nutritional, sensory, and quality properties. Considering the practical feasibility, the procedure used to prepare these products is simple and requires machineries already present in food industries. In addition, the utilization of this coating with walnut-phenolics exerts benefits like, the prevention of allergen cross-contamination in the chain of production, the utilization of an industry's residue, the replacement of synthetic antioxidants and, and the diminishment of the amount and thickness of plastic needed for walnuts' packaging.

A Natural Peanut Edible Coating Enhances the Chemical and Sensory Stability of Roasted Peanuts.

This study aims to assess the enhancement of the chemical and sensory properties of roasted peanuts during storage, through the application of high-protein defatted peanut flour (DPF) coatings incorporated with and without antioxidants. The control sample without coating, packed in normal atmosphere (control), showed the highest conjugated dienes (CD) increment (from 1.17 on day 0 to 3.60 on day 180). Roasted peanuts without coating, packed in high barrier bags under vacuum, reached the lowest CD at day 180 (1.92). Conjugated trienes and peroxide values were analogous to CD. The control exhibited the greatest decrease in α-tocopherol (from 27.65 mg/100 g on day 0 to 21.32 mg/100 g on day 180) and γ-tocopherol (from 21.91 mg/100 g on day 0 to 14.99 mg/100 g on day 180). 3-Methylpyridine and 2,5-dimethylpyrazine decreased with storage time only for the control, which had the highest increase in oxidized flavor (from 0 on day 0 to 13.30 on day 180), cardboard (from 7.67 on day 0 to 15.23 on day 180), and astringency. The lowest decreases in roasted peanutty scores were seen in coated samples. DPF coatings delayed roasted peanuts oxidation, enhancing their sensory properties and shelf life compared with the control sample. PRACTICAL APPLICATION: Defatted peanut flour (DPF) is a byproduct obtained during peanut oil extraction and is a possible material for edible film preparation. This strategy adds value to the peanut industry by transforming a by-product into a material with the potential to develop biodegradable and economical films. The application of this DPF-based edible coating on the surface of roasted peanuts may have contributed to extent product's shelf life, allowing for coated products to be packaged in lower barrier and less expensive materials. Use of peanut material to coat peanuts avoids the risk of allergen protein cross contamination, which would be highly valuable for the food industry.

Thyme and basil essential oils included in edible coatings as a natural preserving method of oilseed kernels.

BACKGROUND: Sunflower seeds are susceptible to developing rancidity and off-flavours through lipid oxidation. Edible coatings and essential oils have proven antioxidant properties in different food products. The purpose of this study was to evaluate the combined effect of using an edible coating and thyme and basil essential oils to preserve the chemical and sensory quality parameters of roasted sunflower seeds during storage. RESULTS: 50% DPPH inhibitory concentration (IC50) values of 0.278 and 0.0997 µg mL(-1) were observed for thyme and basil, respectively. On storage day 40, peroxide values were 80.68, 70.28, 68.43, 49.31 and 33.87 mEq O2 kg(-1) in roasted sunflower seeds (RS), roasted sunflower seeds coated with carboxymethyl cellulose (CMC) (RS-CMC), roasted sunflower seeds coated with CMC added with basil (RS-CMC-A), thyme (RS-CMC-T) and butylated hydroxytoluene (RS-CMC-BHT), respectively. RS-CMC-T and RS-CMC-BHT presented the lowest peroxide values, conjugated dienes and p-anisidine values during storage. RS-CMC-BHT, RS-CMC-T, and RS-CMC-A showed the lowest oxidized and cardboard flavour intensity ratings. On storage day 40, roasted sunflower flavour intensity ratings were higher in RS-CMC-T and RS-CMC-A. CONCLUSIONS: Thyme and basil essential oils added to the CMC coating improved the sensory stability of this product during storage, but only thyme essential oil increased their chemical stability.

Effect of peanut skin extract on chemical stability and sensory properties of salami during storage.

BACKGROUND: Peanut skin extracts (PSEs) have proven antioxidant properties in different food products. The objective of this study was to evaluate the effect of peanut skin extract as natural preserving compounds on chemical stability and sensory properties of salami during storage. RESULTS: PSE was obtained with ethanol-water and added during the preparation of salami samples. Raw salami samples were cured and stored at 15 °C and 65% relative humidity. Moisture, peroxide value, conjugated dienes, free fatty acids and sensory descriptive attributes were evaluated on the samples. Peroxide values increased during storage in all samples and were 82.9 in control (salami without additives), 18.0 in salami with 0.2 g kg(-1) PSE (E0.02), 13.0 in salami with 1.0 g kg(-1) PSE (E0.1), and 0.63 meqO2 kg(-1) in salami with butylated hydroxytoluene (BHT) after 42 days of storage. BHT and E0.1 treatments resulted in a lower increase in the intensity of oxidized flavor and a lower decrease in the intensity of salami flavor. CONCLUSION: Chemical indicators and descriptive results indicated that PSE retards lipid oxidation and preserves sensory properties of salami, prolonging its shelf life.

Effect of storage on chemical and sensory profiles of peanut pastes prepared with high-oleic and normal peanuts.

BACKGROUND: Peanut paste and peanut butter have high oil contents and are thus susceptible to developing rancidity and off-flavours through lipid oxidation. Preservation of the chemical and sensory quality of these products is one of the main problems in the peanut industry. The purpose of this study was to compare the chemical and sensory stability of peanut paste prepared with high-oleic peanuts (cv. Granoleico, GO-P) with that of peanut paste prepared with normal peanuts (cv. Tegua, T-P) from Argentina. RESULTS: Chemical (peroxide and p-anisidine values and conjugated dienes) and sensory (roasted peanutty, oxidised and cardboard flavours) indicators of lipid oxidation were measured in peanut pastes stored at 4, 23 and 40 °C. Chemical indicator values and oxidised and cardboard flavours showed lower increments in GO-P than in T-P during storage. T-P had significantly higher peroxide value than GO-P. Roasted peanutty flavour showed a lower decrease in GO-P. Peanut paste prepared with high-oleic peanuts had four (at 4 °C), two (at 23 °C) and three (at 40 °C) times longer shelf-life than peanut paste prepared with normal peanuts. CONCLUSION: These results indicate that high-oleic Granoleico kernels provide peanut paste with higher protection against lipid oxidation.