Characteristics of pistachio kernel oils from Iranian cultivars

Ten pistachio samples from various Iranian cultivars were examined for some botanical features of their nuts and oil characteristics of their kernels. The wt of 100 nuts varied from 78.5 to 136.9 g. The nuts contained 44.1–58.9% kernel. Moisture of the kernels was low, 2.5–4.1%, and the kernels contained 55.2–60.5% oil. Unsaponifiable matter (0.72–0.96%), saponification value (189.0–193.6), refractive index (1.4635–1.4643), and iodine value (98.1–100.5) showed little differences in various samples. Fatty acids detectable by gas chromatographic analysis were: traces of myristic; 9.2–13.4%, palmitic; 0.5–1.1%, stearic; traces of arachidic; 0.5–1.0%; palmitoleic; 56.1–64.0%, oleic; 22.6–31.0%, linoleic; and 0.1–0.4%, linolenic. There were no significant differences due to origin and/or cultivar of the samples.     

Analysis of volatile compounds in almond and plum kernel oils

Almond and plum kernel oils were analyzed for volatile flavor components by headspace sampling, gas chromatography and mass spectrometry. The most important volatiles at 37°C, from both fruit oils, are derivatives of benzene,n-alkanes, cycloalkanes, aromatics and furan compounds. The structures were established mainly by interpretation of mass spectral data in comparison with literature data.     

Impacts of roasting oily seeds and nuts on their extracted oils

During industrial processing of seeds and nuts to produce edible oils, roasting is often applied before oil extraction. Moreover, seeds and nuts are generally consumed as snack food after appropriate roasting. These processes affect both the seeds and their extracted oils in many ways. Beside changes in macronutrients such as protein denaturation/degradation, oil oxidation, sugar pyrolysis and Maillard reactions, minor constituents such as fatty acids, sterols, phenolic compounds and tocols are also affected by roasting. On the other hand, studies have shown that antioxidant capacity of the roasted seeds and oxidative stability of the extracted oil could be greater than that of the unroasted counterpart. These improvements are attributed to the formation of Maillard reaction products, inactivation of oil degrading enzymes and facilitation of phytochemical extraction as a result of roasting.     

Fatty acid composition of Iranian citrus seed oils

Fatty acid compositions of seed oils from eight Iranian citrus fruits were determined. The ranges of values for major fatty acids were 21.8–29.4% palmitic, 3.1–7.60% stearic, 0.3–1.3% palmitoleic, 23.5–32.3% oleic, 33.5–39.8% linoleic, and 3.1–7.6% linolenic. Low amounts (up to 0.1%) of myristic and arachidic acids and traces of a few unidentified ones constituted minor fatty acids.     

Cardanol in germ and seed oils extracted from cashew nuts obtained by the oltremare process

The presence of cardanol in cashew seed and germ oils was detected by using a combination of the thin layer chromatography (TLC) and gas liquid chroma-tography (GLC) techniques with infrared spectro-scopy (IR) and mass spectrometry (MS). The oils were extracted from cashew nuts obtained by the Oltremare process (heating the nuts in cashew nut shell liquid bath at 180 C for 100–120 sec). The cardanol content was about 40 mg/100 ml of germ oil and 20 mg/100 ml of seed oil. The four cardanol components were found in the following percentages: 3-(pentadecyl)-phenol (II), 3.0%; 3-(8-pentadecenyl)-phenol (III), 55.7%;3-(8,11-pentadecadienyl)-phenol (IV), 24.2%; and 3-(8,l l,14-pentadecatrienyl)-phenol (V), 17.1%, respectively. Because a constant distribu-tion of the four cardanol components was found both in the seed and in the germ oils, it was suggested that cardanol is not a natural component of germ and seed oils, but is derived from the cashew nut-shell liquid during the processing of the nuts.     

Characteristics of coal upgraded with heavy oils

We investigated the ability of an oil coating to upgrade Indonesian low-rank coal, which has a low ash content and a moisture content of approximately 30%. Proximate and ultimate analyses of the characteristics of coal samples containing different amounts of asphalt (ASP) and palm fatty acid distillate (PFAD) were studied, including the samples’ calorific values, crossing-point temperatures (CPT), specific surface areas, pore sizes, structural changes, and moisture readsorption. The results showed that the 0.5% PFAD-coated coal was the highest quality. This coal showed few physical and chemical changes, and it had a low surface area and a high CPT value.     

Characteristics and composition of six malvaceae seeds and the oils

The seeds ofSida veronicifolia Linn., syn.S. bumilis cav.,S. cordifolia Linn.,S. ovata Forsk.,S. mysorensis W & A., syn.S. urticaefolia W & A,S. rhombifolia var.retusa Masters andAbutilon crispum Medik. (Malvaceae) contained 15.5%, 11.5%, 12.1%, 13.2%, 20.2% and 12.5% oil, and 15.0%, 14.1%, 17.3%, 13.6%, 12.6% and 18.4% protein, respectively. Linoleic acid predominated (54.9–69.4%) as the fatty acid of all the oils, and malvalic (1.3–11.4%) and sterculic acids (0.4–1.1%) were significant.     

Free primary alcohols in oils and waxes from germs,kernels and other components of nuts,seeds, fruits and cereals

The composition of free primary alcohols in oils and waxes obtained from the germ, kernel, seed coat, shell and skin (peel) of various nuts, seeds, fruits and cereals and from the chrysalis of silkworm was examined. These alcohols are usually present in small amounts, along with large quantities of hydrocarbons, esters and glycerides in oils and waxes. Thus, it is necessary to remove hydrocarbons, esters and glycerides to analyze the alcohols. We found that preparative reverse-phase thin-layer chromatography (TLC) was the best way to isolate alcohols from oils and waxes. Gas liquid chromatography (GLC) then detected hexacosanol, octacosanol and triacontanol in the oils and waxes. Octacosanol usually was the predominant alcohol. Relationships between the organs from nuts, seeds, fruits and cereals and the contents of octacosanol are suggested. For example, degermed kernels contained two times more octacosanol than the germ, and the skin coat and shell contained one-half and one-fortieth the octacosanol of the germ, respectively.     

Characteristics of safflower seed oils of turkish origin

Technological characteristics of oils extracted from seventeen varieties of safflower seeds (Carthamus tinctorius L.) of Turkish origin were investigated for their utilization prospects in the food industry and in other industrial sectors. Standard procedures were applied to determine the technological characteristics of seventeen varieties of safflower seeds and the safflower seed oils; fatty acid compositions were determined by gas-liquid chromatography. Results show that safflower seed oils are suitable both for food and industrial purposes.     

Characteristics and composition of melon and grape seed oils and cakes

Watermelon (Citrullus vulgaris) and grape (Vitis vinifera) seeds were investigated for their nutritional quality and oil characteristics. The yields of seeds on an as is basis (edible portion) were 1.6 and 1.8% for grape and melon, respectively. The melonseed on a dry weight basis consisted of 53.6% testa and 46.4% kernel. The crude protein, fat and fiber content were 16.4, 23.1 and 47.7% for melon and 8.2, 14.0 and 38.6% for grape (dry weight basis). Both seeds were found to contain significant levels of Ca, Mg, P and K. The fatty acid profiles showed an unsaturated fatty acid content of 76.1% for melonseed oil and 88.6% for grapeseed oil. The predominant fatty acid in both seeds was linoleic acid. The iodine value, saponification number and acid value were 116, 248 and 0.97 for melonseed oil and 132, 194 and 1.59 for grapeseed oil. The amino acid profiles of both seed cake proteins were determined and compared with hen’s egg protein.     

Characteristics and composition ofAbutilon pannosum andHibiscus panduriformis seeds and oils

The seeds ofAbutilon pannosum (Forst.) Schlecht., syn.A. muti cum (DC.) Sweet, andHibiscus panduriformis Burm. (Malvaceae), respectively, contained 13.4 and 15.4% oil, and 23.0 and 22.2% protein. The respective seed oil had iodine values of 118.4 and 132.4, and saponification values of 194.3 and 188.8. The fatty acid composition (wt %), as determined by gas liquid chromatography, was: palmitic, 21.3, 12.3; stearic, 2.8, 3.2;oleic, 11.7, 10.2; linoleic, 60.7, 74.3; malvalic, 2.2, trace; sterculic, trace, none; and dihydrocum sterculic, 1.3, none, respectively.     

乙醇水剂法提取野山杏仁油及组成成分分析研究

利用乙醇水剂法提取野山杏仁油,通过单因素实验结合响应面优化确定的最佳提取工艺是:乙醇浓度18%,料液比1∶7 g/mL,温度34℃,搅拌转速120 r/min,提取时间120 min。在此条件下,油脂提取率为28.34%,亚油酸和油酸含量分别为23.72%,66.47%,抗氧化能力较强。     

Characteristics of the thiobarbituric acid reactivity of oxidized fats and oils

The thiobarbituric acid (TBA) reactivity of oxidized methyl linoleate, soybean oil, sesame oil, lard, chicken oil and sardine oil was characterized by using four different methods with 0.01% butylated hydroxytoluene (BHT). Optimal pH for the reactivity of most of the oxidized samples was 3–4, and that of some samples was above 5. Introduction of 2 mMt-butyl hydroperoxide (t-Bu00H) or 0.2 mM ferric ion in the reaction markedly enhanced the reactivity. Introduction of 0.2 mM ethylenediamine tetraacetic acid suppressed the reactivity. The characteristics of the TBA-reactivity of the samples were similar to those of alkadienals or alkenals. The most preferable method for the estimation of the TBA-reactive substances of the oxidized fats and oils was that using solvents at pH 3.5 with introduction of BHT, andt-Bu00H or ferric ion.     

乙醇水剂法提取野山杏仁油及组成成分分析研究

利用乙醇水剂法提取野山杏仁油,通过单因素实验结合响应面优化确定的最佳提取工艺是:乙醇浓度18%,料液比1∶7 g/mL,温度34℃,搅拌转速120 r/min,提取时间120 min。在此条件下,油脂提取率为28.34%,亚油酸和油酸含量分别为23.72%,66.47%,抗氧化能力较强。     

Characteristics of jet fuels produced from hydrogenated shale oils

Shale oils from the United States (Geokinetics, Occidental, Paraho and Tosco II) were hydrotreated, fractionated into jet fuel cuts (boiling range 121–300°C), then characterized to evaluate their suitability as jet fuels. Nitrogen content was considerably higher, though the amount of hydrogen was relatively lower, than in typical petroleum jet fuels. Sulfur content was significantly below the acceptable limit. Trace metal contents in shale oil jet fuels were below the maximum levels for those in petroleum jet fuels. Vanadium, copper, lead and alkali metals were not present. Physical properties, except freezing points, were comparable to those of standard jet fuels.     

Determination and Comparison of Oil Characteristics in Iranian Almond,Apricot and Peach Nuts

Oil characteristics of sweet and bitter kernels of 5 Iranian cultivars of almond, apricot and peach were determined. Fatty acid composition and fat constants of peach oil were very similar to those of almond oils. Apricot oils were considerably different from almond and peach oils. The differences, however, did not seem to be valuable for any practical use.     

Quality comparison of coke nuts

The strength, reactivity, and technical analysis of coke nuts are discussed. Nuts from gross coke contain 20% more of the (19?C25)-mm size class than for blast-furnace siftings. Compared to wet-slaked coke nuts, dry-slaked coke nuts are characterized by higher hot and cold strength, higher carbon content, and reduced reactivity.     

Physical properties of oils and mixtures of oils

The physical properties of palm, palm kernel and coconut oils are reviewed and compared and contrasted with the properties of other oils and fats. More information is available for palm oil than for the other two. The properties of mixtures of the oils also are considered, especially mixtures of palm and palm kernel oils in which a eutectic interaction occurs. Basic physical properties considered are density, specific heat, heat of fusion and viscosity. Where appropriate, data is tabulated in SI and Imperial units. Experimental methods used for determining melting points and solid fat contents are discussed and the empirical nature of the results emphasized. Wiley melting points and Slip melting points, and Solid Fat Content by NMR and Solid Fat Index by dilatometry, are compared and comparative data given. For palm oil, detailed olein and stearin information is presented. The phase behavior and polymorphism of the three oils is reviewed. Special attention is given to the post-hardening phenomenon in palm oil and the effects of diglycerides and storage time on phase behavior.     

Characteristics and compositions ofCarissa spinarum,Leucaena leucocephala andPhysalis minima seeds and oils

The seeds and extracted oils ofCarissa spinarum (Apocynaceae), (I),Leucaena leucocephala (Leguminosae) (II) andPhysalis minima (Solanaceae) (III) were analyzed for characteristics and compositions. The seeds of I, II and III contained 22.4, 6.4 and 40.0% oil and 10.1, 27.6 and 17.9% protein, respectively. The oils of I, II and III had, respectively, iodine values 70.1, 113.5 and 122.5; saponification values 186, 188 and 189; unsaponifiable matter 5.2, 2.5 and 0.8%, and the following fatty acid compositions (area %): palmitic 12.6, 14.2, 10.5; stearic 7.6, 6.1, 8.6; oleic 72.7, 20.1, 17.3; linoleic 5.2, 53.8, 61.4; linolenic 0.9, 1.8, 0.0, and arachidic 1.0, 2.3, 0.0. II contained 1.7% lignoceric acid. III contained small amounts of hexadecenoic (0.1%), epoxy (0.6%) and hydroxy (1.5%) fatty acids.     

Antiradical activity of extracts of almond and its by-products

Antioxidant activities of ethanolic extracts of whole almond seed, brown skin, and green shell cover were evaluated using different free radical trapping assays. Trolox equivalent antioxidant capacity assay revealed that the total antioxidant capacities of brown skin and green shell cover extracts were 13 and 10 times greater than that of the whole seed extract at the same extract concentration. The free radical-scavenging activity of extracts of brown skin and green shell cover also exceeded that of the whole seed. The scavenging activity of superoxide radical by different almond extracts ranged from 76 to 97% at 100 ppm and 85 to 99% at 200 ppm. The corresponding reduction of hydrogen peroxide concentration was 59–66% (100 ppm) and 86–91% (200 ppm). The hydroxyl radical-scavenging capacities at 100 and 200 ppm were 16 and 42% for whole seed, 57 and 100% for brown skin, and 40 and 56% for green shell extracts, respectively. A 100% scavenging activity of the 2,2-diphenyl-1-picrylhydrazyl (DPPH) radical was observed for brown skin and green shell extracts at 100 and 200 ppm concentrations, respectively, and whole seed extracts scavenged 21 (at 100 ppm) and 73% (at 200 ppm) of the DPPH radical.