Total lipid content and fatty acid composition of the seeds of some Vicia L. species

The seed oils of eight Vicia species (Leguminosae) were investigated for their total lipid contents and fatty acid compositions. The seed lipid contents were found to be between 2.30 and 3.91%. The fatty acid compositions of these eight different species were determined by gas chromatography of the methyl esters of their fatty acids. The seed oils of Vicia species contain palmitic and stearic acids as the major component fatty acids, among the saturated acids, with a small amounts of myristic, pentadecanoic, arachidic and behenic acids. The major unsaturated fatty acids found in the seed oils were oleic, linoleic and linolenic acids.     

Identification of bioactive compounds and total phenol contents of cold pressed oils from safflower and camelina seeds

The compositions of fatty acids, tocopherols, polyphenols, sterols, and the total phenol contents of cold pressed oils obtained from five varieties of safflower seeds and ten varieties of camelina seeds cultivated in Turkey were determined. Total phenol contents of safflower oils were higher (272.20–525.30 mg GAE/kg) than camelina seed oils (25.90–63.70 mg GAE/kg). Apigenin, luteolin, tyrosol, syringic acid, 3-hydroxytyrosol, p-coumaric acid and sinapic acid were detected in seed oils. Camelina seed oils were rich in tocopherol (144.11–168.69 mg/100 g). γ-Tocopherol was the predominant tocopherol in camelina seed oils consisting of averagely 80% of total tocopherol, while α-tocopherol was the main compound of safflower seed oils, representing 97.85–98.53% of total tocopherols. β-Sitosterol was the major sterol in both type of seed oils. Its concentration ranged between 92.51–121.83 mg/100 g and 80.52–25.54 mg/100 g in safflower seed and camelina oils, respectively. Camelina seed oils contained 22.31–26.57% linolenic acid, 21.25–24.05% linoleic acid and 19.46–21.47% oleic acid, whereas safflower seed oils mainly consisted of linoleic (28.03–76.85%) and oleic (13.01–62.61%) acids.     

The distribution of fatty acids in the seed oils of the compositae,liliaceae, ranunculaceae and sapindaceae families

The oil content and fatty acid composition of the seed oils of Compositae (five species), Goodeniaceae (three species), Liliaceae (three species), Ranunculaceae (three species) and Sapindaceae (three species) were determined. The fatty acid composition of the seed oils were analysed by gas chromatography. In the 17 species studied the seed oil fatty acids were dominated by linoleic acid (50.1–70–5%) followed by oleic (11.1–20–4%) and palmitic acids (9.0–13–3%), except in one species, Diplopeltis huegelii, in which oleic acid (35.1%) predominated.     

The fatty acid and tocopherol constituents of the seed oil extracted from 21 grape varieties (Vitis spp.)

BACKGROUND: Fatty acids and tocopherols in appropriate quantities are invaluable attributes that are desirable in seeds of agricultural products. Studies have generally focused on the evaluation of the oil and tocopherol components of oil crops. Recently, investigations revealed that the grape seed has robust potential in the production of healthy fatty acids as well as tocopherols. This study was thus conducted to determine the oil and tocopherol components of grape seeds, obtained from various grape cultivars of different species, including two rootstock varieties. RESULTS: The grape seed oil concentration of the studied varieties ranged from 7.3 to 22.4%. The determined fatty acid profiles of the genotypes conformed to the pattern described in the literature for grapes. Linoleic acid is the major component comprising 53.6–69.6% of the total, followed by oleic (16.2–31.2%), palmitic (6.9–12.9%) and stearic (1.44–4.69%). The oils of all the seeds analysed showed a preponderance of α‐tocopherol (ranging from 260.5 to 153.1 mg kg^?1 oil extract). β‐Tocopherol, γ‐tocopherol and δ‐tocopherol were also detected with the general means of 0.98, 22.2 and 0.92 mg kg^?1, respectively. Linoleic acid showed a significantly negative correlation with all the fatty acids analysed. The strongest negative correlation existed between linoleic and oleic acids (r = ? 0.834, P < 0.01). CONCLUSION: Present investigations indicated that oil content, fatty acid composition and tocopherol constituents of grape seed show great variation among the genotypes. Markedly higher proportions of linoleic acid with considerable amounts of tocopherols found in the oil samples suggest that grape seed is a good source for culinary, pharmaceutical and cosmetic uses. Copyright © 2012 Society of Chemical Industry     

Oil,micronutrient and heavy metal contents of tomatoes

In this study, oils, micronutrients and heavy metal contents of tomato seeds and tomato (Lycopersicon esculentum) fruits from different Turkish resources were determined. The tomato seed oil contains more than 84% unsaturated fatty acids, such as oleic acid, linoleic acid and linolenic acid. The fatty acid composition of tomato seed oil was similar to that of soybean oil. Under supercritical conditions, partial thermal degradation occurs on the double bonds of unsaturated aliphatic carbons chains in fatty acids. Linoleic acid was the major unsaturated fatty acid in tomato seed oil. The concentrations of metals (Pb, Cd, Fe, Cu, Zn, Na, K, Ca and Mg) were determined in tomato samples.     

Antiradical and antimicrobial properties of cold-pressed black cumin and cumin oils

Cold-pressed black cumin seed oil (BCSO) and cumin seed oil (CSO) were evaluated for their fatty acid profiles, phytosterol and tocopherol contents, antiradical properties and inhibition of microbial growth. The main fatty acids in BCSO were linoleic followed by oleic and palmitic acids. Petroselinic acid (C18:1n-12) was the main fatty acid in CSO, while linoleic acid was the second major unsaturated acid. Six sterol compounds were measured in BCSO and CSO, wherein the sterol marker was β-sitosterol. α-Tocopherol constituted 45% of tocopherols in BCSO, while β-tocopherol was the main component in CSO. BCSO and CSO oils had higher antiradical action against DPPH· and galvinoxyl radicals than virgin olive oil. Antimicrobial properties of BCSO and CSO were studied, and the results revealed that CSO inhibited the growth of all microorganisms tested, while BCSO inhibited the growth of all microorganisms tested except A. niger and A. flavus. BCSO and CSO had a drastic effect on the biosynthesis of protein and lipids in cells of B. subtilis.     

八角金盘籽油和果油的超声波-微波协同提取及其脂肪酸组成比较

采用微波-超声协同提取法,通过正交优化制备八角金盘籽油和果油,并比较两种油脂的理化特性和脂肪酸组成。结果表明：提取时间90 s、微波功率250 W、液料比10 mL/g 时,籽油出油率为34.43%;提取时间150 s、微波功率250 W、液料比10 mL·g-1 时,果油出油率为11.32%。籽油出油率明显比果油高。两种油脂除碘值外,其他理化指标差异不明显,其理化指标均达到GB / T 2716-2018食用植物油国家标准。籽油的主要脂肪酸为十五碳一烯酸(3.08%)、亚油酸(7.04%)、油酸(87.42%),其中不饱和脂肪酸相对含量为98.64%;果油的主要脂肪酸为花生酸(0.96%)、亚麻酸(1.71%)、硬脂酸(3.25%)、棕榈酸(5.08%)、油酸(25.96%)、亚油酸(61.61%),不饱和脂肪酸含量为89.52%。本研究为八角金盘油脂的开发利用提供了科学依据和技术参考。     

Essential oil,fatty acid and sterol composition of Tunisian coriander fruit different parts

BACKGROUND: Seed and pericarp of coriander fruit were compared in terms of essential oil, fatty acids and sterols. RESULTS: Essential oil yield of coriander samples ranged from 0.30 to 0.68% (w/w) in fruit and seed, respectively. However, in pericarp, the essential oil yield was only of 0.04% (w/w). Linalool was the major compound in the whole fruit, seed and pericarp, with 86.1%, 91.1% and 24.6% of the oils, respectively. Fatty acid composition of pericarp and seed lipids were investigated by gas chromatography. Petroselinic acid was the main compound of fruit and seed, followed by linoleic and oleic acids. Palmitic and linoleic acids were estimated in higher amounts in pericarp lipids. Total sterol contents were 36.93 g kg^?1 oil in seed, 6.29 g kg^?1 oil in fruit and 4.30 g kg^?1 oil in pericarp. Fruit and pericarp oils were characterized by a high proportion of β‐sitosterol, with 36.7% and 49.4% of total sterols, respectively. However, stigmasterol (29.5%) was found to be the sterol marker in seed oils. CONCLUSION: Coriander oil is a rich source of many compounds such as essential oils, fatty acids and sterols. This compound distribution presented significant differences between whole fruit, seed and pericarp. Copyright © 2009 Society of Chemical Industry     

Comparison of fatty acid profiles and contents of seed oils recovered from dessert and cider apples and further Rosaceous plants

To get a more comprehensive knowledge of oil contents and fatty acid pattern, seed oils from various Rosaceous plants belonging to the subfamilies Maloideae and Rosoideae, respectively, were investigated. For this purpose, isolated seeds of 18 dessert and cider apple (Malus domestica BORKH.) cultivars of different provenances, pear (Pyrus communis L.), rose hip (Rosa canina L.), quince (Cydonia oblonga Mill.), and red chokeberry (Aronia arbutifolia L.) were analyzed for their oil content and fatty acid composition. Oil contents varied significantly, not only among the different genera, but also among cultivars of one species, ranging from 0.8 to 29.4?g/100?g?dry matter. Qualitatively, the fatty acid profiles of the investigated seed oils showed good agreement in all representatives of the Rosaceae. Their triacylglycerols were uniformly composed of linoleic, oleic, palmitic, stearic, palmitoleic, α-linolenic, arachidic, gondoic, and behenic acids. Quantitation of individual fatty acids revealed the oils to be rich in mono- and diunsaturated oleic acid and linoleic acid, ranging from 15.1 to 33.3?g/100?g and from 32.5 to 49.7?g/100?g, respectively. As expected, contents of saturated fatty acids were 6–10?times lower. Moreover, apple cultivars showed pronounced differences in yields, numbers, and weights of their seeds. As demonstrated by the data obtained from this study, seeds resulting from the processing of apple, pear, quince, chokeberry (Maloideae), and rose hip (Rosoideae) into juices, jellies, and jams may serve as a promising source for the recovery of nutritionally valuable edible oils.     

Seed compositional studies of some species of Papilionoideae (Leguminosae) native to Argentina

Seeds of 17 wild leguminous species belonging to the Papilionoideae subfamily were analysed for their proximate, fatty acid and sterol compositions. Centrosema virginianum, Tipuana tipu, Adesmia volckmanni and some species of Desmodium contained high amounts (>300 g kg^?1) of protein. Geoffroea decorticans and Clitoria cordobensis were noteworthy for their high oil content (>350 g kg^?1). The seed lipids had a high proportion of unsaturated (oleic and linoleic mainly) fatty acids. Linolenic acid had the highest value in Adesmia volckmanni (25.4% of total fatty acids). β‐Sitosterol was the major component of the sterol fraction. Chemical analyses indicated that all species studied are suitable sources of animal feed. © 2002 Society of Chemical Industry     

Oil Content and Fatty Acid Composition of Seeds of Guizotia Cass (Compositae)

Seeds of Guizotia abyssinica and wild Guizotia were analysed for oil content and fatty acid composition by multisequential and gas chromatographic methods, respectively. The oil content of G abyssinica ranged from 416 to 436 g kg^-1 (weight per kg dry matter of seeds) and that of the wild Guizotia taxa from 214 to 328 g kg^-1. Two unsaturated fatty acids (linoleic (54·3–72·8, weight percent of total oil) and oleic (5·4–26·8% of oil by wt) and two saturated fatty acids (palmitic (7·8–10%) and stearic (5·5–8·1%)) were about 91–97% of the fatty acids present. Palmitoleic, linolenic, arachidic, eicosenoic, behenic, erucic and lignoceric acids constituted about 2–3%. An unidentified fatty acid, probably an epoxy form of C: 20 or C: 22, has been found in all the materials and it was 1·1–6·6%. Total saturated and unsaturated fatty acids were about 74–84% and 15–20%, respectively. Differentiation in fatty acid composition between the taxa is too small to be of taxonomic use. It is inferred that when gene transfer is desired hybridisation between the wild and cultivated taxa may not affect the oil quality of the latter and the oils of the wild taxa are possibly safe for human consumption. © 1997 SCI.     

GC-TOF-MS定性和定量评估5 种木本油料种籽油的脂肪酸

采用气相色谱-飞行时间串联质谱和超临界二氧化碳提取技术,分析评价5 种木本油料种籽油的脂肪酸组成及相对含量。油茶和榛子种籽油中富含油酸,亚油酸是沙棘和文冠果种籽油中的主要脂肪酸,牡丹种籽油中的亚麻酸含量最高。沙棘种籽油的单不饱和脂肪酸与饱和脂肪酸比值为1.57：1,亚油酸与亚麻酸的比值为1.56：1,符合功能性健康食用油的标准;牡丹种籽油是补充人体ω-3脂肪酸的优质食用油;油茶和榛子种籽富含单不饱和脂肪酸,适合食品加工;文冠果种籽油含有3 种长链单不饱和脂肪酸（如神经酸等）。本实验评价了5 种木本油料油脂脂肪酸的组分,对指导企业生产生物活性油和人们的健康消费具有重要意义。     

Seed oils of apples (Malus pumila)

Apple seed oils were found to be characterised by a high content of linoleic acid (48–64 %), together with 24–42 % oleic acid, 48–71 % palmitic acid and lesser percentages of stearic and arachidic acids. The Granny Smith seed oils contained significantly greater amounts of palmitic and linoleic acids than those of the Dougherty and Sturmer varieties and lesser amounts of oleic acid. Differences in fatty add composition between the Sturmer and Dougherty varieties were not significant. The apple seed oils contrasted with those of other sub-families of the family Rosaceae in containing neither a-elaeostearic acid nor more than traces of linolenic acid. The apple processing industries could well be a useful source for the production of oil rich in linoleic acid.     

Identification of the composition of fatty acids in Eucommia ulmoides seed oil by fraction chain length and mass spectrometry

In order to automatically identify fatty acids in plant seed oils, a method was developed to search all saturated fatty acid methyl esters in the sample, subsequently calculate the ECL value of each fatty acid, and finally identify the molecular structure for each component by comparing the ECL of the interest and that in the customised database. Our method was applied to analyse the fatty acid composition of Eucommia ulmoides seed oil. The results show that major polyunsaturated fatty acids are α-linolenic acid (56.5093% of total fatty acids, TFAs) and linolelaidic acid (12.6563% of TFAs). Meanwhile, the main monounsaturated fatty acid is oleic acid whose percentage in the TFAs is 15.8008. Palmitic acid and steartic acid are the dominant saturated fatty acids representing 9.8165% and 2.5942% of TFAs, respectively. The UFA/SFA ratio (6.57) is higher than the recommended value (3) by nutritionists.     

Analysis of Hiptage madablota seed oil

Hiptage madablota seed kernels yield a pale yellow oil (67·0%) which is rich in ricinoleic acid (70·0%). The seed oil also contains the following acids: caprylic, capric, myristic, palmitic, stearic, oleic, linoleic, arachidic and behenic.     

Total lipids content and fatty acid composition of seed oils from six pomegranate cultivars

The fatty acid composition of the seed oils of six pomegranate (Punica granatum L) cultivars was qualitatively and quantitatively determined by gas chromatography. The seeds contained oil in the range 51-152 mg kg^?1 dry matter. Intervarietal differences in fatty acid composition were demonstrated (fatty acid esters as % (w/w) total fatty acid esters. Sour varieties had the highest while sour-sweet varieties had the lowest oil content. Eleven fatty acids were identified. In all varieties, the predominant fatty acids were linoleic (25.2-38.6%) and oleic acid (24.8-35.5%) followed by palmitic (18.2-22.6%), stearic (6.9-10.4%) and linolenic acid (0.6-9.9%). To a lesser extent arachidic (1.1-3.4%) and palmitoleic acid (0.2-2.7%) were also found in all varieties. Lauric, myristic, behenic and lignoceric acids were rarely detected. As far as we know linolenic (18:3), arachidic (20:0), behenic (22:0) or lignoceric (24:0) acids have not been previously reported in the seed oils of edible pomegranate varieties. Lignoceric acid has not previously been found in pomegranate seed oil.     

Composition and antioxidative activities of supercritical CO2-extracted oils from seeds and soft parts of northern berries

The present study investigated the composition and the antioxidative activities of oils from the seeds and the soft parts of a range of northern berries extracted by supercritical CO₂. The seed oils of the species of Rubus, Vaccinium, Empetrum, Fragaria and Hippophaë were rich in linoleic (18:2n-6, 34-55% of total fatty acids) and ??-linolenic (18:3n-3, 29-45% of total) acids with n-6:n-3 ratios of 1:1-1:2. The seed oils of the species Ribes contained, in addition to linoleic and ??-linolenic acids, ??-linolenic (18:3n-6) and stearidonic (18:3n-4) acids. In seed oils from European rowanberry (Sorbus aucuparia L.) and snowball berry (Viburnum opulus L.), linoleic and oleic (18:1n-9) acids together exceeded 90% of the total fatty acids. The sea buckthorn (SB) pulp oil had palmitoleic (16:1n-7), palmitic (16:0) and oleic acids as the major fatty acids. The SB pulp oil and snowball berry seed oil were rich in ??-tocopherol (120 and 110 mg/100 g oil, respectively), whereas raspberry seed oil contained a high level of ??-tocopherol (320 mg/100 g oil). Seed oils of cranberry (180 mg/100 g oil), Arctic cranberry (190 mg/100 g oil) and lingonberry (120 mg/100 g oil) are rich sources of ??-tocotrienol. The berry seed oils and the SB pulp oil showed varying peroxyl radical scavenging efficacies (300-2300 ??mol ??-tocopherol equivalent per 100 g oil) and inhibitory effects on perioxidation of microsomal lipids (250-1200 ??mol trolox equivalent per 100 g oil) in vitro. The peroxyl radical scavenging activity positively correlated with the total content of tocopherols and tocotrienols of the oils (r = 0.875, P = 0.001). The SB seed oil and pulp oil were active in scavenging superoxide anions produced by xanthine-xanthine oxidase system and inhibited Cu²⁺-induced LDL oxidation in vitro. The SB oils also protected purified DNA and rat liver homogenate from UV-induced DNA oxidation in vitro. The current research suggests potential of supercritical CO₂-extracted oils from northern berries as nutraceuticals and ingredients of functional foods.     

Inhibition of Bacillus cereus spores and vegetative cells by fatty acids and glyceryl monododecanoate

Fatty acids and glyceryl monododecanoate (monolaurin) inhibited cell growth from Bacillus cereus spores and vegetative cells. The inhibitory activity decreased according to: stearic < oleic < linoleic < lauric < monolaurin < linolenic. Vegetative cells were similarly affected by monolaurin, oleic and linolenic acids but were less sensitive to linoleic or lauric acids than their spores.Lauric acid (0·075 to 0·5 mM) inhibited cell multiplication, oleic acid (0·885 to 1·060mM) affected solely spore germination, whereas monolaurin (0·073 to 0·109 mM), linoleic (0·178 to 0·321 mM) and linolenic acids (0·036 to 0·054 mM) inhibited both spore germination and outgrowth.The effects of stearic and oleic acids were reversible whereas linoleic (0·885 to 1·065 mM) totally and irreversibly inactivated spores. Other inhibitors partially affected spores and vegetative cells.Starch neutralized the inhibitory activity of fatty acids except for lauric acid 1 mM and oleic acid. Starch antagonism decreased as fatty acid concentration increased.     

Variation in oil content and fatty acid composition of the seed oil of Acacia species collected from the northwest zone of India

BACKGROUND: The oil content and fatty acid composition of the mature seeds of Acacia species collected from natural habitat of the northwest zone of the Indian subcontinent (Rajasthan) were analyzed in order to determine their potential for human or animal consumption. RESULTS: Oil content varied between 40 and 102 g kg^?1. The highest oil content was obtained in Acacia bivenosa DC. (102 g kg^?1) among the nine Acacia species. The fatty acid composition showed higher levels of unsaturated fatty acids, especially linoleic acid (～757.7 g kg^?1 in A. bivenosa), oleic acid (～525.0 g kg^?1 in A. nubica) and dominant saturated fatty acids were found to be 192.5 g kg^?1 palmitic acid and 275.6 g kg^?1 stearic acid in A. leucophloea and A. nubica respectively. Seed oils of Acacia species can thus be classified in the linoleic–oleic acid group. Significant variations were observed in oil content and fatty acid composition of Acacia species. CONCLUSION: The present study revealed that the seed oil of Acacia species could be a new source of high linoleic–oleic acid‐rich edible oil and its full potential should be exploited. The use of oil from Acacia seed is of potential economic benefit to the poor native population of the areas where it is cultivated. The fatty acid composition of Acacia seed oils is very similar to that reported for commercially available edible vegetable oils like soybean, mustard, sunflower, groundnut and olive. Hence the seed oil of Acacia species could be a new source of edible vegetable oil after toxicological studies. Copyright © 2012 Society of Chemical Industry     

Chemical characterization of Cleome dolichostyla seed oil

Oil extracted from C. dolichostyla seeds constituted 31·2% of the whole seed. Results of the physical and chemical analyses of the oil for iodine number, saponification number, Hehner value, Reichert-Meissl number and refractive index compared well with the characteristics of other commonly consumed vegetable oils. Thin-layer chromatography, in conjunction with gas-liquid chromatography, revealed a relatively high degree of unsaturation, 84·1%, with a linoleic acid content of 52·2 followed by oleic, 30·6%; palmitic, 10·1%; stearic, 4·49% and linolenic, 1·17%. Based on these data, C. dolichostyla seed oil might have potential as an edible oil for human and/or animal consumption. However, toxicity studies on the safety of this oil are still needed.