Search Results (1,818)

This research aimed to explore the influence of climate factors, especially in the three weeks prior to harvest, on the reaction of key phytonutrients in industrial tomatoes used for juice thermal processing and their stability. The cultivation was performed in two areas with differing climatic conditions. In the region with higher temperatures and rainfall, the levels and stability of carotenoids were lower compared to the area characterized by warm temperatures and minimal rainfall during both the growth and harvest phases of the tomatoes. The extraction of cold-break (CBE) tomatoes from relatively cool and wet environments resulted in a loss of total carotenoids, particularly lycopene, amounting to 66% and 58% of the initial raw tomato content in 2018 and 2019, respectively, while a markedly reduced loss of 10% was observed after the CBE of tomatoes from the warmer and drier region in both years (36% and 35%). In contrast, hot-break extraction (HBE) demonstrated a higher stability of lycopene compared to CBE, with losses of 43% and 53% in 2018 and 2019, respectively. Additionally, the stability of lycopene in HBE did not show significant differences between the cultivation sites. Climatic conditions influenced the accumulation of geometrical isomers and oxidized forms of lycopene and β-carotene, especially in tomatoes grown in areas with higher rainfall and lower temperatures. A similar trend in response was noted for β-carotene, lutein, phytoene, and phytofluene, as well as total and individual tocopherols. Regarding vitamin C, the environmental factors had no meaningful impact on the vitamin content in tomato fruits; however, its stability during processing, especially with hot-break extraction, was considerably influenced by the climatic conditions of the cultivation site, with p values ranging from <0.01 to <0.001 across different products in various years. The content and stability of phytonutrients in pomace, the by-product from tomato juice processing, were also assessed. In conclusion, tomato fruits and processed products that boast high phytonutrient levels and stability during thermal processing can be achieved through cultivation in conditions of low rainfall and relatively high temperatures, particularly in the three weeks leading up to harvest. Full article

Berry seeds represent an underexploited byproduct of juice and wine production, and are increasingly valued sources of high-quality cold-pressed oils. In this study, eight berry species, including blackcurrant (Ribes nigrum), red currant (Ribes rubrum), raspberry (Rubus idaeus), strawberry (Fragaria), sea buckthorn (Hippophae rhamnoides), honeysuckle (Lonicera caerulea), viburnum (Viburnum opulus), and rowanberry (Sorbus aucuparia), were investigated to determine the impact of primary fermentation on seed composition and oil quality. Seeds obtained from juice production were compared with those obtained after fermentation. Fermentation consistently reduced seed sugars and carbohydrates by more than 50% while increasing relative protein levels, demonstrating microbial utilization of fermentable substrates. Oil yields showed species-specific responses, with blackcurrant and honeysuckle seeds increasing from ~14 to 15% and ~7 to 8%, respectively, while raspberry decreased from ~9 to 8%, and viburnum decreased from ~6 to 5%. Importantly, fatty acid profiles remained unchanged across all treatments, confirming that fermentation does not alter the natural dominance of linoleic and α-linolenic acids. Tocopherol and total phenolic contents decreased modestly in fermented oils (typically 5–10%), which was reflected in small reductions of DPPH scavenging activity (2–4%) and oxidative stability (0.2–0.5 h). A multivariate heatmap and PCA analyses revealed that berry species identity was the primary driver of biochemical variation, while fermentation introduced only minor within-species shifts. The results indicate that berry pomace remaining after fermentation can still be valorized for cold-pressed oil production with minimal compromise in quality. Full article

Heracleum persicum Desf. ex Fischer, a species of the Apiaceae family, is endemic to Iran and has been historically utilized as a spice, condiment, and medicinal plant. The plant produces seeds that represent a potential new source of vegetable oil. In this study, the oil from these seeds was extracted using a solvent, and its physical, chemical, and nutritional properties were investigated. The oil extraction yield was determined to be 12.62%. Oleic acid (61.11%) and linoleic acid (25.84%) were identified as the predominant fatty acids in the extracted oil. Among its phytosterols, beta-sitosterol (65.6%) and stigmasterol (14.0%) were the most abundant. Furthermore, this oil exclusively contained alpha-tocopherol at a relatively high concentration (1610.9 ppm). The chlorophyll and carotenoid contents of the extracted oil were 28.34 mg/kg and 4.95 mg/kg, respectively. Regarding its nutritional indices, the atherogenic index, thrombogenic index, and hypocholesterolemic to hypercholesterolemic ratio were 0.13, 0.24, and 9.77, respectively. In conclusion, considering its unique oil composition and qualitative characteristics, this oil holds promise as a novel source of vegetable oil and a valuable byproduct of Heracleum persicum. Full article

Background/Objectives: The prebiotic effect of resistant potato starch (RPS) has been demonstrated, but the antioxidant properties associated with this ingredient have not been explored. Methods: We performed post hoc analysis of serum metabolomic data from a clinical trial evaluating 3.5 g RPS per day consumption (n = 24) versus a placebo (n = 24) for 4 weeks in a randomized clinical trial (NCT05242913). Results: Levels of the exogenous antioxidants all-trans retinol and α-tocopherol increased in the RPS-consuming group. Among endogenous antioxidants, the concentration of coenzyme Q10 (CoQ10) increased in both treatment groups, while uric acid was unaffected. Hippuric acid, a marker of polyphenol metabolism, was unaffected by treatment, as was the abundance of the tryptophan metabolites kynurenine and 3-hydroxyanthranillic acid. However, levels of 3-hydroxykynurenine were decreased in both treatment groups. Levels of the advanced glycation end products NƐ-(1-carboxymethyl)-L-lysine and NƐ-(1-carboxyethyl)-L-lysine, markers of chronically elevated oxidative stress, were unaffected by treatment. Notably, increases in serum all-trans retinol were correlated with increases in Akkermansia. Conclusions: RPS enhances the absorption of antioxidants all-trans retinol and α-tocopherol from the diet and also influences CoQ10 levels and tryptophan metabolism. Future studies assessing the physiological consequences of enhanced antioxidant absorption in people consuming RPS over a longer duration are warranted. Full article

The objective of this study was to investigate the effects of fractionation by sieving on cold-pressed camelina cake by separating it into particle-sized fractions and evaluating their nutritional and functional properties. Two Camelina sativa varieties, NS Zlatka and NS Slatka, were mechanically cold-pressed using a screw press then ground into flour. The resulting material was fractionated into three particle-sized fractions, >250 µm, 250–180 µm, and <180 µm, using a laboratory dry sieving system. Both the whole cake and the separated fractions were analyzed for proximate composition, amino acid and fatty acid profiles, tocopherol content, antioxidant potential, color characteristics, and water and oil absorption capacities. The results indicated that the finest cake fraction (<180 µm) from both camelina varieties contained the highest content of protein (~40%), fat (17–19%), essential amino acids (~17 g/100 g), γ-tocopherols (254–266 mg/kg), and the lowest content of condensed tannins (0.5–0.9 g/kg). It also displayed a lighter color and increased yellowness. However, it contained the highest concentrations of glucosinolates (24–27 μmol/g) and phytic acid (38–41 g/kg). In contrast, the coarsest fraction (>250 µm) had increased crude fiber content (13–15%), higher antioxidant potential, the greatest water absorption capacity, and a darker color with a more pronounced reddish color. It also contained the lowest levels of glucosinolates (19–21 μmol/g) and phytic acid (17–20 g/kg). In conclusion, whole camelina cake and its fractions demonstrate considerable potential for use in animal feed and a variety of human nutritional products, due to their favorable nutritional composition and functional properties. Fine fractions with high levels of antinutritional compounds could be used as a substrate for the extraction of bioactive compounds and may find further application in the cosmetic and pharmaceutical industries. Full article

The olive tree (Olea europaea L.) has been cultivated for millennia, with olive oil representing both a cornerstone of the Mediterranean diet and a major agricultural commodity. Its composition, rich in monounsaturated fatty acids, polyphenols, tocopherols and squalene, supports well-documented cardioprotective, antioxidant and anti-inflammatory benefits. Olive oil production generates substantial secondary streams, including pomace, leaves, pits and mill wastewater, which are rich in phenols, triterpenes and fibers. This review consolidates recent advances in their phytochemical characterization, innovative extraction technologies and health-promoting effects, while highlighting the economic and regulatory prospects for industrial adoption. Comparative analysis shows that olive leaves can produce up to 16,674.0–50,594.3 mg/kg total phenolics; oleuropein 4570.0–27,547.7 mg/kg, pomace retains 2.24 g GAE/100 g dried matrix (DM)total phenolics; oil 13.66% DM; protein 6.64% DM, and wastewater contains high concentration of phenolics content of olives. Innovative extraction techniques, such as ultrasound and microwave-assisted methods, allow for a recovery, while reducing solvent use and energy input. The analysis highlights opportunities for integrating these by-products into circular bioeconomy models, supporting the development of functional foods, nutraceutical applications and sustainable waste management. Future research should address techno-economic feasibility, regulatory harmonization and large-scale clinical validation to accelerate market translation. Full article

Trichilia emetica and T. dregeana butter oils are gaining recognition in the cosmeceutical industry, yet comparative data on their yields and bioactive composition remain scarce. This study assessed oil yields, fatty acid profiles, and tocol compositions of kernel and aril oils extracted by screw press from seeds collected in KwaZulu-Natal, South Africa. T. emetica produced smaller but more numerous seeds (603 per 200 g) than T. dregeana (159). Kernel oil yields were slightly higher in T. emetica (52.86%) than in T. dregeana (50.81%), while aril oils averaged 48.61% and 45.22%, respectively. Kernel oils of both species showed strong oxidative stability, with low peroxide and anisidine values and lower free fatty acid content compared to aril oils. T. emetica kernel oil was dominated by saturated fatty acids (SFAs), particularly palmitic acid (51.8%), and contained high γ-tocopherol (202 mg/kg), supporting applications in soaps, bio-lubricants, and industrial formulations. In contrast, T. dregeana kernel oil was richer in oleic acid (47.6%) and α-tocotrienol, favouring nutraceutical and cosmetic uses. Aril oils were dominated by linoleic acid (24–25%), with T. dregeana aril oil distinguished by elevated α-tocopherol (91.8 mg/kg) and a more diverse tocotrienol profile, making it suitable for antioxidant-rich cosmetics and dietary products. The dual-oil system offers complementary value: kernel oils provide structural stability for industrial applications, while aril oils supply bioactive-rich lipids for health and cosmetic formulations. Seed cakes present additional potential as biofertilizers or feedstock. This study provides the first comparative analysis of kernel and aril oils from T. emetica and T. dregeana, revealing interspecific differences in yield, fatty acid composition, and tocol profiles, and linking these to ecological adaptation and differentiated industrial potential. Full article

This work has reviewed the recently published literature (last 8 years) about the effects caused by HPP on the antioxidant properties (A, C, and E vitamins and antioxidant activity) of F&V (fruits and vegetables) preparations in comparison to thermal treatments (TP). The methodology of this revision was performed mainly by using keywords related to HPP, F&V, and antioxidant compounds in the Scopus database. High-pressure technology was briefly described, considering its principles and historical milestones, and justifying that it can be applied as a green and sustainable preservation method (with pros and cons). It is also relevant for the present food market due to their growing tendency in F&V derivatives (especially juices). The main effects on vitamins and antioxidant compounds point to it as an emerging preservation method to maintain and avoid vitamin and bioactive substances loss in comparison with pasteurization by heat. Maximum efficiency, cost-effectiveness, and quality improvement are aspects to be improved in the future by HPP technologies. Full article

Soybean (Glycine max (L.) Merr.) is one of the most important global economic crops, extensively utilized in the production of food, animal feed, and industrial raw materials. As the demand for soybeans continues to rise, improving both the yield and quality of soybeans has become a central focus of agricultural research. To accelerate the genetic improvement of soybean, genome selection (GS) and genome-wide association studies (GWAS) have emerged as effective tools and have been widely applied in various crops. In this study, we conducted GWAS and GS model evaluations across five soybean phenotypes (Glycitin content, Oil, Pod, Total isoflavone content, and Total tocopherol content) to explore the effectiveness of different GWAS methods and GS models in soybean genetic improvement. We applied several GWAS methods, including fastGWA, BOLT-LMM, FarmCPU, GLM, and MLM, and compared the predictive performance of various GS models, such as BayesA, BayesB, BayesC, BL, BRR, SVR_poly, SVR_linear, Ridge, PLS_Regression, and Linear_Regression. Our results indicate that markers selected through GWAS, when used in GS, achieved a prediction accuracy of 0.94 at a 5 K density. Furthermore, Bayesian models proved to be more stable than machine learning models. Overall, this study offers new insights into soybean genome selection and provides a scientific foundation for future soybean breeding strategies. Full article

This study investigated the effects of ultrasonic treatment of olive paste prior to malaxation on oil yield (Y), enzyme activity and virgin olive oil (VOO) quality in four Croatian olive varieties: Istarska Bjelica, Rosulja, Oblica and Levantinka. The oils were extracted using the Abencor system according to a central composite experiment design, with treatment durations of 3–17 min and power levels of 256–640 W. The parameters analyzed included Y, oxidative stability index (OSI), antioxidant capacity (AC), phenolic and α-tocopherol content, volatile compounds, fatty acid profile, and the activity of lipoxygenase, β-glucosidase, polyphenol oxidase, and peroxidase. Olive variety was the most influential factor in all variables. The response surface methodology showed that ultrasonic treatment at low-to-medium intensity improved several quality attributes. For example, Y increased by 4% in Oblica, phenolic content increased by up to 17% in Istarska Bjelica, and OSI and AC increased by 13–15% in Istarska Bjelica and Levantinka. In contrast, longer treatment and higher ultrasound power had a negative effect. No significant differences were found in other parameters examined. Overall, the application of ultrasound led to measurable, though moderate, improvements in Y and VOO quality, with results strongly dependent on olive variety and treatment conditions. These results underline the need for further optimization tailored to each variety. Full article

It was hypothesized that differences in production system and muscle type may influence the formation of lipid oxidation products (LOP) as well as protein oxidation (protein carbonyl compounds, PCC) during the in vitro gastrointestinal digestion of chicken meat. To test our hypothesis, we investigated the formation of LOP and PCC after heating and in vitro gastrointestinal digestion of conventional and organic chicken breast and thigh meat and Wooden Breast meat. Prior to the in vitro digestion, thigh and breast meat was minced and heated. Digests of organic thigh meat had significantly higher levels of all LOP measured compared to conventional thigh meat (between +37% and +173%). Lower levels of LOP were found in digests of breast meat regardless of the production system and Wooden Breast phenotype. LOP correlated positively with heme-Fe and polyunsaturated fatty acids, negatively with anserine, and not with carnosine and α-tocopherol. PCC levels were significantly higher in thigh meat than in breast meat after heating (+43%) and digestion (+25%), irrespective of the production system. Overall, organic thigh meat exhibited the highest oxidative sensitivity during digestion. The cut-dependent differences in composition and oxidative susceptibility between organic and conventional chicken highlight the need for further research to assess potential health implications. Full article

Apricot kernels (Prunus armeniaca L.) represent a valuable by-product of stone fruit cultivation, offering diverse applications in food, cosmetic, and pharmaceutical industries. While apricot kernel oil is recognized for its rich composition of unsaturated fatty acids, phenolics, and tocopherols, its therapeutic potential, particularly in cancer prevention, remains unexplored. This study investigated a purified fraction (FOPF) obtained from Farclo variety kernel oil, cultivated in the Emilia-Romagna region of Italy and selected for its naturally low amygdalin content. In vitro studies demonstrated FOPF’s significant antiproliferative effects against colorectal cancer (LoVo, HT29) and hepatocarcinoma (Hep3B) cell lines, with GI₅₀ values ranging from 0.06 to 0.09 mg/mL. The fraction induced cell cycle arrest and significantly inhibited cancer cell migration, effects mediated through PPAR-γ expression modulation. These findings establish FOPF’s potential as a natural chemopreventive agent and provide a foundation for its development as a nutraceutical ingredient targeting colorectal and hepatic cancers. Full article

This study investigated how different spectral ranges of LED light affect the synthesis of photosynthetic pigments and antioxidant systems in Thymus mastichina L., focusing on two ecotypes with distinct chemotypes: linalool and eucalyptol. The ecotypes were exposed to white, red, blue, red-blue (70:30), white-blue, or white-red light for 30 days under a 16/8 h light/dark cycle (115 μmol/m²s). Photosynthetic pigment content, lipid oxidative damage, antioxidant capacities, and both enzymatic (SOD, CAT) and non-enzymatic (tocopherols and polyphenols) antioxidant systems were assessed. For the linalool chemotype, red-blue light significantly increased carotenoid content, antioxidant capacity, and catalase activity, while elevating levels of plastochromanol-8 and phenolic compounds such as salvianolic acid B, rosmarinic acid, and 6-OH-apigenin-7-hexoside, thereby reducing oxidative stress. In contrast, for the eucalyptol chemotype, pure red light produced the most significant enhancements in carotenoid synthesis and antioxidant defenses, substantial increases in key compounds such as salvianic, neochlorogenic, rosmarinic, and lithospermic acids, and salvianolic acids E and B, and higher levels of plastochromanol-8. Additionally, both SOD and CAT activities increased, providing greater protection against lipid oxidation. These findings highlight the importance of customizing light treatments not only based on plant species but also according to chemotype to obtain optimal biochemical and physiological outcomes. Full article

This work aimed to promote an integrated valorization approach for recovering lipophilic fractions from whole pisco grape pomace using emerging extraction technologies such as Randall (40 °C, 360 min) and Pressurized Liquid Extraction (PLE: 60 °C, 10 min) to characterize lipid-soluble biocompounds and evaluate their functional quality and antioxidant potential. PLE achieved maximum extraction yields (11–15%). Extraction techniques did not significantly alter fatty acid profiles, with C18:2n6c linoleic acid being most abundant (65–69%), followed by C18:1n9c oleic acid (17–21%), while C20:1 eicosanoid acid was least prevalent (1–2%). The fatty acid profile enabled functional potential evaluation through atherogenicity, thrombogenicity, and hypocholesterolemic/ hypercholesterolemic ratios, showing values comparable to other lipid sources. α-Tocopherol content was significantly influenced by extraction techniques (87–645 μg/g), while polyphenol content showed no significant differences between methods (0.6–0.8 mg GAE/g extract). Randall demonstrated higher DPPH radical scavenging capacity (25–30%), while PLE presented higher ORAC values (68–120 μmolTE/g extract). This represents the first characterization of lipophilic fractions from this pomace type, highlighting how emerging extraction techniques affect recovery of high-quality, antioxidant-rich fractions. Results suggest their potential as functional biocompound sources and candidates for various applications, contributing to grape waste valorization strategies. Full article

Background: Skin whitening agents often face challenges such as poor stability and low permeability. To overcome these issues, a novel 4-butylresorcinol (4-BR)/D-a- Tocopherol Polyethylene Glycol Succinate (TPGS) deep eutectic solvent (DES) system was developed, which can self-assemble into carrier-free nanoparticles (NPs). Methods: The 4-BR/TPGS DES was synthesized and characterized by theoretical calculations, DSC, FTIR, 1H-NMR, and 2D NMR to confirm its successful formation. Results: The self-assembled 4-BR/TPGS DES NPs showed a 3.46-fold increase in skin permeability, a 1.53-fold improvement in 4-BR stability, a 1.55-fold increase in melanin inhibition in B16 cells, and a 2.16-fold higher melanin suppression in zebrafish compared with traditional 4-BR oil-based formulations. These results indicated the excellent whitening efficacy and transdermal delivery potential of this formulation. Conclusions: The combination of TPGS-based DES and self-assembly technology represents a revolutionary approach for advanced transdermal delivery and the development of skin care products. Full article