Tocopherols,Tocotrienols and Carotenoids in Kernel Oils Recovered from 15 Apricot (<Emphasis Type="Italic">Prunus armeniaca</Emphasis> L.) Genotypes

We studied the content of tocopherols, tocotrienols and carotenoids in oil extracted from the kernels of 15 apricot (Prunus armeniaca L.) genotypes and the associated oil yield of the studied samples. The oil yield in apricot kernels was in a wide range of 27.2–61.4% (w/w) dry weight basis. For each class of studied compounds (tocochromanols and carotenoids), a three-fold difference was found between the lowest and the highest content (78.8–258.5 and 0.15–0.53 mg/100 g of oil, respectively). γ-Tocopherol accounted for 91–94% of total tocochromanols detected in all tested samples. Lutein, zeaxanthin, β-cryptoxanthin and β-carotene were the main compounds among the eight different carotenoids detected in apricot kernel oils; they comprised 76–94% of the total carotenoids content, and compositions were characteristic for specific genotypes. The oil yield and content of lipophilic antioxidants in apricot kernel oils were significantly affected by the genotype. The oil yield was negatively correlated with the total amount of tocochromanols (r = ?0.910) and carotenoids (r = ?0.704) in apricot kernel oils.     

Milk Thistle Seed Oil Constituents from Different Varieties Grown in Iran

In this study, fatty acids, phytosterol classes and tocopherols composition of Milk thistle seeds oil were determined at four varieties grown in Ardebil-Iran. The four varieties consisted of two modified foreign varieties—Budakalaszi (originally from Hungary) and the CN-seed variety (originally from England) and two native varieties, namely Khoreslo and Babak Castle. The oil content of the seeds ranged from 26 to 31%. Among the fatty acids, linoleic acid had the highest percentage (50–54%) followed by oleic acid (23–29%) and palmitic acid (7–8%). This is the first detailed report on the phytosterol classes of milk thistle seeds oil. The 4-Desmethylsterol class was predominant (1,800–2,200 μg/g) followed by 4,4′-dimethylsterols (50–85 μg/g) and 4-monomethylsterols (26–35 μg/g). The α-, β-, γ-, and δ-tocopherols ranged from 187 to 465, 10 to 51, 9 to 12, and 18 to 80 μg/g oil, respectively. Based on the results obtained, the extracted oil from milk thistle seeds are rich in essential fatty acids, sterols and vitamin E and can be an attractive candidate for use in food preparation mixed with other vegetable oils or alone.     

Biochemical Characterization of Turkish Extra Virgin Olive Oils from Six Different Olive Varieties of Identical Growing Conditions

Extra virgin olive oils were extracted from six different major olive cultivars (Gemlik, Ayvalik, Domat, Akhisar, Memecik, Arbequina) cultivated in the Aegean region of Turkey. Fatty acid, sterol and tocopherol compositions were analyzed and the results were compared by multivariate statistical analysis. Olive samples were collected from the same orchard in order to limit the contribution of parameters such as climate, soil quality and agricultural practices to the total variance of chemical composition of olive oils. Principal component analysis (PCA) showed that cultivars can be clearly distinguished on the basis of fatty acid and sterol composition. It is of interest to note that palmitoleic acid content of Arbequina, a Spanish cultivar, is significantly (p < 0.05) higher than the local Turkish cultivars in question and it is the only olive sample whose palmitoleic acid concentration is higher than that of the stearic acid concentration, exhibiting a divergent composition from the local Turkish cultivars. β‐Sitosterol and Δ5‐avenasterol contents of the oils are significantly correlated (r = ?0.989, p < 0.05) and this results in a discriminative axis on the PCA loading plot. Tocopherol composition was relatively insufficient in discriminating the olive varieties. Regarding tocopherol compositions Gemlik cultivar is distinguished from other cultivars with its γ‐tocopherol content, which is in average two times higher than that of other cultivars. The result of the present compositional study provides important data which can be used for olive oil authenticity studies in Turkey.     

Dragon Fruit (Hylocereus spp.) Seed Oils: Their Characterization and Stability Under Storage Conditions

Oil was extracted from the seeds of white-flesh and red-flesh dragon fruits (Hylocereus spp.) using a cold extraction process with petroleum ether. The seeds contained significant amounts of oil (32–34 %). The main fatty acids were linoleic acid (C18:2, 45–55 %), oleic acid (C18:1, 19–24 %), palmitic acid (C16:0, 15–18 %) and stearic acid (C18:0, 7–8 %). The seed oils are interesting from a nutritional point of view as they contain a large amount of essential fatty acids, amounting to up to 56 %. In both dragon fruit seed oils, tri-unsaturated triacylglycerol (TAG) was mainly found while their TAG composition and relative percentage however varied considerably. Therefore, they showed a different melting profile. A significant amount of total tocopherols was observed (407–657 mg/kg) in which the α-tocopherol was the most abundant (~72 % of total tocopherol content). The impact of storage conditions, cold and room temperatures, on the oxidative stability and behavior of tocopherols was monitored over a 3-month storage period. During storage, the oxidative profile changed with a favorably low oxidation rate (~1 mequiv O₂/week) whilst tocopherols decreased the most at room temperature. After 12 weeks, the total tocopherol content, however, still remained high (65–84 % compared to the initial oils). Hereto, the dragon fruit seed oils can be considered as a potential source of essential fatty acids and tocopherols, with a good oxidative resistance.     

Comparison of Fatty Acid, Sterol, and Tocol Compositions in Skin and Kernel of Turpentine (Pistacia terebinthus L.) Fruits

Pistacia terebinthus L. is an indigenous plant growing wild in the southern regions of Turkey. Its fruits are used in foods, pharmaceuticals and cosmetics due to its high oil content (ca. 45 g/100 g). In the present study, it was found out that the kernel and the skin parts of the fruit differ significantly (p < 0.05) both in terms of oil content and composition. Regardless of the geographical origin, the most abundant fatty acid was found to be monounsaturated oleic acid, 18:1n-9 whose content was in the range of 51.2–67.5 g/100 g. β-sitosterol is the predominant sterol in kernel and skin of the terebinthus fruits whose content was varying between 97.4 and 219.8 mg/100 g. Concerning different tocols (tocopherols and tocotrienols) detected in the kernel and skin, γ-T was the one with highest concentration (437.2 mg/kg) in kernels, while the most abundant one in skin parts was found to be α-T (348.7 mg/kg). In general the kernel of terebinthus fruits was more concentrated in PUFA, total sterol and tocopherols than skin, however, total tocotrienol content was higher in skin than kernel. On the basis of these findings it can be concluded that both kernel and skin are highly valuable in terms of bioactive compounds, whereas skin with a high amount saturated fatty acids is more suited to applications in cosmetic industry.     

Variations in Fatty Acids,Phospholipids and Sterols During the Seed Development of a High Oleic Sunflower Variety

The changes in the content and composition of total fatty acids, phospholipids and sterol esters, and their fatty acids, and of free sterols and tocopherols in developing seeds of a selection of high oleic acid sunflower varieties grown in Bulgaria were examined over a period of 15th to 90th day after flowering by means of various chromatographic methods. Under the climatic and geographical conditions typical for the South-East Balkans phospholipid, sterol-, sterol ester- and tocopherol- species are formed practically completely in the first 15 days after flowering. Until the 90th day, only quantitative changes were detected to give a product with 65% oil content, 1% phospholipids, 0.3% total sterols and 0.09% tocopherols. Oleic acid is the main component in all acyl derivatives, reaching 85% of the total fatty acids while palmitic and stearic acid content is about 4% each. The product is a good quality HOSO with beneficial content of FA and good prospects as a salad and cooking oil.     

Lipid Classes and Subclasses of Cold-Pressed and Solvent-Extracted Oils from Commercial Indian Niger (Guizotia abyssinica (L.f.) Cass.) Seed

Lipid classes and subclasses of cold-pressed and solvent-extracted (hexane and ethanol) oils from commercially available niger (Guizotia abyssinica (L.f.) Cass.) seeds were investigated. The oil yield of niger seeds obtained by cold pressing was 28.3 g/100 g while by hexane and ethanol extractions was 38.3 and 29.7 g/100 g respectively. The lipid classification of the extracted niger seed oils showed neutral lipids (65.9–95.5 %), glycolipids (2.7–24.6 %) and phospholipids (1.8–9.5 %). The acylglycerol composition of neutral lipids of extracted niger seed oils showed triacylglycerols (76.9–91.6 %), diacylglycerols (3.9–7.3 %) and monoacylglycerols (0.6–2.5 %). The fatty acid composition of tri-, di-, and monoacylglycerols of extracted niger seed oils showed linoleic acid (66.7–71.6 %) as the major fatty acid. The triacylglycerol composition of neutral lipids of extracted niger seed oils showed trilinolein (39.2–40.3 %) as the major triacylglycerol. The extracted niger seed oils contained 1289.9–6215.8 ppm of total phytosterols with β-sitosterol (41.9–43.7 %) as the major phytosterol. Acylated steryl glucoside (39.5–52.2 %) was the major glycolipid in extracted niger seed oils. Phosphatidylcholine (49.6 and 47.9 %) was the major phospholipid in cold-pressed and hexane-extracted niger seed oils and phosphatidylethanolamine (57.1 %) was the major phospholipid in ethanol-extracted niger seed oil. This is probably the first report on the variations in lipid classes and subclasses of Indian niger seed oil as affected by different modes of oil extraction.     

Chemical Composition,Anti-oxidant,and Antimicrobial Activities of Four Saline-Tolerant Plant Seed Oils Extracted by SFC

The supercritical CO₂ fluid extraction process was used to obtain seed oils. The compositional analyses of the seed oils of Amorpha fruticosa L., Caragana microphylla Lam and Elaeagnus angustifolia L. were performed by GC–MS, from which 18–22 fatty acid compositions were identified, and their main components were linoleic acid (49.10–66.39 %) and oleic acid (11.95–41.10 %). The seed oils were rich in unsaturated fatty acids, which accounted for 79.75–91.19 %. The in vitro anti‐oxidant activities of the seed oils were measured by the DPPH, ABTS and phosphomolybdenum complex assays. The IC₅₀s of the seed oils were 6.5110–12.6599 mg/mL tested by DPPH assay, and the IC₅₀s were in the range of 0.6872–1.9310 mg/mL tested by ABTS assay. The anti‐oxidant activities of seed oils decreased in the order of A. fruticosa > C. microphylla > E. angustifolia (A) > E. angustifolia (D). In vitro antimicrobial activities of seed oils against five bacteria were tested by microdilution method. The MIC values of the oils against Bacillus subtilis, E. coli, S. aureus, P. solanacearum and B. thuringiensis were in the range of 26–36, 30–38, 58, 56–58 and 56–58 mg/mL, respectively, while the MBC values were in the range of 30–40, 34–42, 58, 56–58 and 58 mg/mL, respectively. In vitro antifungal properties of the seed oils against four plant pathogenic fungi were tested by the mycelial growth rate method. The EC₅₀s of seed oils against V. mali, C. gloeosporioides, F. graminearum and B. cinerea were in the range of 17.51–19.25, 15.58–19.12, 8.00–17.12 and 18.76–19.14 mg/mL, respectively. The seed oils showed moderate anti‐oxidant and antimicrobial activities.     

Stability of Cold-Pressed Oil from Commercial Indian Niger (Guizotia abyssinica (L.f.) Cass.) Seed as affected by Blending and Interesterification

Blending and interesterification of cold‐pressed oil from commercially available niger (Guizotia abyssinica (L.f.) Cass.) seeds was performed to improve its stability. The fatty acid composition of cold‐pressed niger seed oil (NSO) revealed that it contained a huge amount of polyunsaturated linoleic acid (69.2 %). NSO being rich in polyunsaturated fatty acids (PUFA) was susceptible to oxidation and hence was blended with saturated fatty acid (SFA) rich coconut oil (CNO) and monounsaturated fatty acid (MUFA) rich olive–pomace oil (OO) to enhance its stability. CNO contained a total of 91.3 % of SFA, while OO had oleic acid, C18:1 (74.3 %) as MUFA. Two blends of NSO with CNO and OO, i.e. NSO + CNO(B) and NSO + OO(B), were prepared in the ratio of 1:1. The blends were further interesterified using the lipase enzyme from Rhizomucor meihei and interesterified oils, i.e. NSO + CNO(I) and NSO + OO(I), were obtained. The oxidative stability of the oils was evaluated by incubating them at 37 °C and 55 % relative humidity (RH) for a period of 45 days. The peroxide values of NSO + CNO(B), NSO + OO(B), NSO + CNO(I) and NSO + OO(I) showed a reduction by 53.3, 42.6, 65.3 and 55.4 %, respectively, while the conjugated diene values showed a reduction by 75.0, 66.9, 76.7 and 75.3 %, respectively, as compared to NSO during the incubation period. This is probably the first report on the stability improvement of niger seed oil through blending and interesterification.     

Physico-Chemical Characteristics of Citrus Seeds and Seed Oils from Pakistan

The physico-chemical characteristics of the seeds and seed oils of four citrus species, Mitha (Citrus limetta), Grapefruit (Citrus paradisi), Mussami (Citrus sinensis), and Kinnow (Citrus reticulata) were investigated. The hexane-extracted oil content of citrus seeds ranged from 27.0 to 36.5%. The protein, fiber and ash contents were found to be 3.9–9.6%, 5.0–8.5%, and 4.6–5.6%, respectively. The extracted oils exhibited an iodine value of 99.9–110.0; refractive index (40 °C), 1.4639–1.4670; density (24 °C), 0.920–0.941 mg/mL; saponification value, 180.9–198.9; unsaponifiable matter, 0.3–0.5%; acid value (mg KOH/g of oil), 0.5–2.2 and color (1-in. cell) 1.4–3.0R + 15.0–30.0Y. The oils revealed a good oxidative stability as indicated by the determinations of specific extinctions at 232 and 270 nm (2.3–4.4 and 0.6–0.9, respectively), p-anisidine value (2.2–3.2) and peroxide value (1.6–2.4 mequiv/kg of oil). The citrus seed oils mainly consisted of linoleic acid (36.1–39.8%). Other prominent fatty acids were palmitic acid (25.8–32.2%), oleic acid (21.9–24.1%), linolenic acid (3.4–4.4%), and stearic acid (2.8–4.4%). The contents of tocopherols (α, γ, and δ) in the oil were 26.4–557.8, 27.7–84.1, and 9.1–20.0 mg/kg, respectively. The results of the present study demonstrated that the seeds of citrus species investigated are a potential source of valuable oil which might be utilized for edible and other industrial applications.     

Enzyme‐assisted aqueous extraction of oil and protein from canola (Brassica napus L.) seeds

The emphasis of this study was to investigate the effect of enzymes on aqueous extraction of canola (Brassica napus L.) seed oil and protein. Four enzymes, Protex 7L, Multifect Pectinase FE, Multifect CX 13L, and Natuzyme, were tested for their effectiveness in releasing oil and protein during aqueous extraction. The enzyme‐extracted oil content of canola seeds (22.2–26.0%) was found to be significantly (p <0.05) higher than that of the control (without enzyme) (16.48%). An appreciable amount of protein (3.5–5.9%) originally present in the seed was extracted into the aqueous and creamy phases during aqueous extraction of oil. The physicochemical properties of oils extracted from canola seed by conventional solvent extraction, and aqueous extraction, with or without enzyme addition were compared. Significant (p <0.05) differences were observed in free fatty acid content, specific extinctions at 232 and 270 nm, peroxide value, color (1‐inch cell) and concentration of tocopherols (α, γ, and δ). However, no significant variation (p <0.05) was observed in iodine value, refractive index (40 °C), density (24 °C), saponification value, unsaponifiable matter and fatty acid composition. A better oil quality was obtained with aqueous extraction (with and without enzyme) than with solvent extraction. While the enzymes enhanced the oil extraction, the oil yield was still significantly (p <0.05) lower than that obtained by solvent (hexane) extraction.     

腊梅花不同开放状态的精油成分分析

采用水蒸气蒸馏法提取腊梅花精油,采用气相色谱-质谱联用技术(GC-MS)对精油成分进行分析,研究花蕾、初展、全展3种不同开放状态腊梅花中精油化学成分的变化。结果表明,3种不同状态的腊梅花精油主要成分基本相同,其中,芳樟醇含量随着开放度的增大,含量发生显著变化,并在初展状态达到峰值,质量分数为11.72%,其他主要香气成分的含量变化不大。     

假酸浆子胶质的乳化性评价

评价了假酸浆子胶质的乳化性。结果表明,假酸浆子胶质能降低油水界面张力;乳状液稳定性随胶质质量浓度增加而增强,加油量增多而下降。乳化温度和贮存温度越高,乳状液越不稳定。胶质溶液pH改变胶质溶液的黏度进而影响乳状液稳定性。pH=3时,胶质溶液乳化活性(emulsion ability,EA)和乳化稳定性(emulsionstability index,ESI)达最高值,分别为1.247和63.353 h。乳状液粒径随质量浓度和均质压力增大而减小。均质压力过大会导致乳状液放置后易聚集而不稳定,合适的均质压力为5 MPa。     

Profiling of the Beneficial and Potentially Harmful Components of Trichodesma indicum Seed and Seed Oil Obtained by Ultrasound-Assisted Extraction

The beneficial and potentially harmful bioactive components in the seeds and seed oil of Trichodesma indicum L. (Boraginaceae) were investigated in the present study. The T. indicum seeds were rich in oil (29.0%), phenolic compounds (PC, 1881.2 mg per 100 g), and pyrrolizidine alkaloids (PA, 2,702,338 ng g⁻¹). Seven PC were identified in T. indicum seeds by liquid chromatography-quadrupole-time-of-flight mass spectrometry system (LC-Q-TOF-MS). Rosmarinic acid (67%) and isomers of salvianolic acid B/E/L (26%) were the main phenolics, while melitric acid A and sebestenoid C/D constituted 6% and 1%, respectively. Only a minor part of the total PC and PA was transferred from the seeds into the oil fraction during the extraction procedure (<0.03%). The T. indicum seed oil was predominated by the following polyunsaturated fatty acids (PUFA):linoleic (23.2%), γ-linolenic (6.0%), α-linolenic (26.8%), and stearidonic (5.9%). High levels were also observed for oleic (26.7%) and palmitic (7.4%) acids. Additionally, notable amounts of γ-tocopherol (92% of total tocochromanols) and β-sitosterol (53% of total sterols) were found in T. indicum seed oil. The total content of tocochromanols, sterols, and carotenoids in T. indicum seed oil was 102.7, 236.0, and 0.6 mg per 100 g oil, respectively. Among 10 detected hepatotoxic PA in T. indicum seeds, intermedine/lycopsamine/indicine (90.9%), intermedine N-oxide (4.9%), and lycopsamine N-oxide (4.1%) consisted 99.9% of the total PA concentration. The T. indicum seeds should be used carefully due to the presence of PA.     

微波辅助顶空固相微萃取法分析印度草木犀不同部位挥发油化学成分

采用微波辅助顶空固相微萃取法提取印度草木犀不同部位的挥发油,通过气相色谱-质谱法与Kovats色谱保留指数相结合进行定性定量分析。结果表明,在印度草木犀的茎、叶和花中分别鉴定出43、44和71个组分,分别占挥发油总峰面积的89.92%、83.12%和90.77%,在茎中主要成分是3,4-二氢香豆素(5.97%),二氢香豆素(55.29%)和十六醛(4.44%)。叶中主要成分是3,4-二氢香豆素(11.84%),二氢香豆素(48.15%)。而在花中主要是3,4-二氢香豆素(6.08%),二氢香豆素(27.44%),对异丙基苯甲醚(6.20%)和麝香草酚(5.19%)。结果显示,不同部位相同化学成分其相对质量分数有一定的差异性。     

Characterization of Monovarietal Argentinian Olive Oils from New Productive Zones

Quality characteristics (acidity, peroxide value, K ₂₃₂, K ₂₇₀, ΔK, oxidative stability index) and chemical data (antioxidant compound, fatty-acid, sterol, erythrodiol-uvaol, and wax compositions) were studied in monovarietal virgin-olive oil samples (2004–2005 harvests) from different regions of Argentina. The data obtained according to standard methods were compared with international quality and purity criteria. The total-polyphenol content ranged from 25 to 263 mg/kg, showing the highest values for Coratina and Arauco oils. The α-tocopherol content varied between 160 and 428 mg/kg; these values are generally stated to belong to good quality oils. Most of the samples from the new productive zones failed at least one purity criterion. Arbequina samples presented the highest deviations from the International Olive Oil Council criteria in fatty acids, waxes, and sterol percentages, indicating a poor adaptation of this cultivar to the agronomic medium and its sensibility to adverse climatic conditions. Principal component analysis revealed that the harvest-year influence was attributable to environmental factors.