• Journal of Nutrition and Health
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• v.28 no.4
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• pp.268-281
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• 1995

This study was undertaken to elucidate the effect of DHA-rich fish oil (DHA-rich oil) added to different dietary fats on lipid metabolism. Rats were fed perilla oil, sesame oil and beef tallow with or without DHA-rich oil for 12 weeks. The weight gain was higher in groups with DHA-rich oil than that of groups without DHA-rich oil, with DHA-rich oil, while weight of epididymal fat pad was lower in perilla oil and beef tallow groups with DHA-rich oil. The contents of total lipid and triglyceride in plasma were not affected by dietary fat types, but that of total and HDL cholesterol in plasma were higher in sesame oil group than perilla oil and beef tallow groups without DHA-rich oil. The contents of total lipid, triglyceride, total cholesterol, HDL cholestrol and LDL cholesterol in plasma were decreased by DHL-rich oil addition. The contents of total lipid, total cholesterol and triglyceride in the liver were not affected by dietary fat type. The contents of total cholesterol and triglyceride in the liver were not affected by dietary fat type. The contents of total lipid and TG in liver were not affected by DHA-rich oil addition while hepatic cholesterol increased by DHA-rich oil addition. The activities of glucose 6-phosphate dehydrogenase and malic enzyme were highest in beef tallow group without DHA-rich oil and decreased by DHA-rich oil addition. Peroxisomal ${\beta}$-oxidation had an inverse relationship against the activities of lipogenic enzymes. In conclusion, dietary DHA-rich oil decreased fat accumulation and had hypolipidemic effect, especially in beef tallow group. Also groups with DHA-rich oil showed more hypolipidemic effect than perilla oil group. And DHA-rich oil addition to diets resulted in increasing dietary n-3/n-6 ratio. Therefore increase in n-3/n-6 ratio as well as dietary DHA were considered to be responsible for the hypolipidemic effect resulted from DHA-rich oil addition.

• Journal of Nutrition and Health
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• v.13 no.4
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• pp.177-186
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• 1980

Experiments were carried out in order to compare the sesamol contents in the methanol extracts and unsaponifiable matters from raw and baked seeds of Korean sesame and perilla by thinchrography. The oil and sesamol contents of sesame seeds were higher than those of perilla seeds. The contents of sesamol in raw and baked sesame seeds were 0.22 and 0.096% respectively in methanol extracts and 0.41 and 0.29% respectively in unsaponifiable matters. The sesame contents in raw and baked perilla seeds were 0.0022 and 0.0043% respectively in methanol extracts and not detected in unsaponifiable matters.

• KOREAN JOURNAL OF CROP SCIENCE
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• v.51 no.1
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• pp.95-100
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• 2006

Sesamin and sesamolin, antioxidant lipidsoluble lignan compounds, are abundant in sesame (Sesamum indicum L.) seed oil and provide oxidative stability of oil related to sesame quality. The sesamin and sesamolin contents of 403 sesame land races of Korea were determined by HPLC analysis of methanol extract (HPLC value), and their total lignan content was compared with those by using UV-Vis spectrophotometric analysis (UV method) of methanol (UV-MeOH value) and hexane (UV-Hexane value) extracts. HPLC values of total lignan content were strongly associated with UV-Hexane (r=0.705**) and UV-MeOH (r=0.811**) values. The UV values from both the extracts were 3.8-4.7 times higher than those of HPLC values. Lignan content was overestimated by UV method because total compounds in the mixture solution were quantified by absorbing at the same ultraviolet wavelength as in HPLC method. UV method could more rapidly analyze small amount of sample with higher sensitivity of detection than HPLC method. Average contents of lignans in sesame germplasm evaluated in this study were $2.09{\pm}1.02mg/g$ of sesamin, and $1.65{\pm}0.61mg/g$ of sesamolin, respectively, showing significant variation for lignan components. The results showed that UV method for the determination of sesamin and sesamolin could be practically used as a faster and easier method than HPLC by using the regression equations developed in this study.

• Journal of the Korean Society of Food Science and Nutrition
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• v.6 no.1
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• pp.49-53
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• 1977

Fatty acid composition of commercial oil were analyzed with gas liquid chromatography. Sesame, perilla, rice bran, sunflower, and soy-bean oil were obtained from the whole sale store of edible oil in market. The fatty acids were methylated with Na-methylate. The fatty acid methylester was charged to the gas liquid chromatography. Sesame were composed of myristic, palmitic, stearic. linoleic acid, and trace of linolenic acid. Rice bran, and soy-bean oil were composed of myristic, stearic, oleic, linoleic, and linolenic acid. Peilla oil was composed of palmitic, stearic, oleic, linoleic, and linolenic acid. Sunflower oil was composed of palmitic, stearic, oleic, and linoleic acid.

• The Korean Journal of Food And Nutrition
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• v.34 no.2
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• pp.217-223
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• 2021

Vegetable oils are a rich source of bioactive substances. Phytosterols in those have been known for many years for their properties for reducing blood cholesterol levels, as well as their other beneficial health effects. Phytosterols are triterpenes that are important structural components of plant cell membranes just as cholesterol does in animal cell membranes. The aim of this study was to provide consumers with information about phytosterol contents in vegetable oils in Korea market. The contents of major phytosterols (campesterol, stigmasterol, β-sitosterol) in 50 vegetable oils of 10 kinds (perilla oil, peanut oil, avocado oil, olive oil, pine nut oil, sesame oil, canola oil, coconut oil, grape seed oil, and sunflower oil) were analyzed by gas chromatography with flame ionization detector. The average contents of vegetable oils containing 5 or more samples were in the order of sesame oil (334.43 mg/100 g), perilla oil (262.16 mg/100 g), grape seed oil (183.71 mg/100 g), and olive oil (68.68 mg/100 g). Phytosterol content of sesame oil and perilla oil was high among vegetable oils.

• KSBB Journal
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• v.20 no.3
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• pp.205-209
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• 2005

Studies for the commercial production of sesame oil using th supercriticl carbon dioxide were made. Characteristics of sesame oil containing one of natural antioxidant 'sesamol', which only exist at sesame seed were also studied during the supercritical fluid extraction. Among the various factors influencing the sesamol contents in the sesame oil, the roasting time and temperature were checked, because sesamol can be converted from sesamol in through pyrolysis. We found that the sesamol content was increased rapidly under the condition of roasting temperature over $200^{\circ}C$ with longer roasting time. The sesamol content was increased as the temperature and pressure increased, which was caused by increase of solubility of sesamol against sesamol oil. And the sesamol content was increased also with lower speed of supercritical fluid, which increased the contact time with the raw material. The sesamol content was also increased using water increase up to $1\%$ as the entrainer. When the extraction performance with the supercritical fluid was compared to the conventional compressed extraction, the sesamol content was increased up to 11.5 times with the entrainer.

• KOREAN JOURNAL OF CROP SCIENCE
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• v.48
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• pp.65-71
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• 2003

Sesame seed are one of the oldest oil-bearing crops known to man. Not only are they nutritious, they are physicologically beneficial. Because of these properties, the promotion of sesame as a crop is set to increase from now on. The lignan component of sesame, which has an antioxidative function, varies considerably. In addition, the seeds remain viable for longer than other crops. At low temperature, it has been reported that the seed remain viable for up to thirty years. This is due to the lignan content of the seeds. In the last twenty years, the mysteries of the natural chemistry of sesame seeds have been unravelled one by one. Up to now, the lignan component has been found to have an $\alpha$-tocopherol synergist effect, an anti-aging effect, a cancer suppressing effect, a hypertension reduction effect, an effect on the promotion of liver function, an effect on the control of the ration of unsaturated fat, and an effect on the synthesis of unsaturated fatty acids. The lignan component of sesame does not simply have an anti-oxidant function, but has diverse recently discovered physiological uses which make the study of lignan highly rewarding.

• Applied Biological Chemistry
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• v.23 no.1
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• pp.14-22
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• 1980

White and black sesame produced in Korea were defatted with ethyl ether or n-hexane. Defatted sesame meal was extracted with water and salt solution, and protein extraction was precipitated at various pH 1 through 12, with trichloro acetic acid (TCA), tannic acid and ammonium sulfate, respectively. Protein was purified by Sephadex A-25, G-75, G-100 and G-200, and identified its protein fraction by polyacrylamide gel electrophoresis. Amino acids composition of protein in white sesame was analyzed by automatic amino acid analyzer. Protein contents of white sesame, black sesame and sesame meal are 20.5%, 19.2%, and 44.7%, respectively. n-Hexane was the most suitable solvent for extraction of oil from sesame. Crude protein precipitation was better in higher pH. The protein extraction was more effective with the solution containing sodium chloride tinder the pH 8. Globulin in total protein was high and prolamin was less than in other cereal proteins. Glutamic acid contents of white sesame and sesame globulin were 17.1%, and 20%, respectively. Both proteins contained relatively high levels of essential amino acids. 12-13 bands were found in water soluble protein and 2 bands in salt soluble protein were detected by the disc gel electrophoresis, and were identified in both of white and black sesame. The salt soluble protein of white sesame could be purified by Sephadee G-100 and G-200.

• KOREAN JOURNAL OF CROP SCIENCE
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• v.55 no.3
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• pp.195-199
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• 2010

This experiment was conducted to develop optimum sesame cultivation practices as succeeding cropping system of watermelon in the greenhouse condition. We also compared major components in sesame seed cultivated in the greenhouse and open field condition. The adaptable varieties under the greenhouse condition were white sesame 'Pyoungan' and black sesame 'Jinki' which showed higher yield and disease resistance. We also conducted several experiments to determine optimum sowing date, planting density and pinching time. Grain yields were statistically different according to the several sowing dates. In general, sesame sowing on June 30th showed higher grain yields than July 10th, July 20th and July 30th in the greenhouse. We also found out sesame cultivation practice with the row spacing of 40 cm and interplant spacing of 30 cm (a few branch type) or 40 cm (many branch type) showed higher yield than other treatments. Optimum pinching time was 25 days after first flowering in main stem when thousand seed weight and grain yield were highest. In the comparison of major components of sesame at the different cultivation conditions, sesame seeds cultivated in the greenhouse contained 4% much more oil content than open field condition. The lignan compounds, sesamin and sesamolin were also higher by 6% in the greenhouse than open field condition. It was concluded that sesame cultivation practices as succeeding cropping system of watermelon in the greenhouse condition guaranteed higher grain yield with less labor input which is now emerging alternative farming practice system in present aging rural society and will also give sesame cultivation farmers to increase net income in Korea.

• Journal of the Korean Society of Food Science and Nutrition
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• v.14 no.4
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• pp.365-369
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• 1985

In order to examine the effect of oil extraction methods on the characteristics of sesame oil, the unsaponifiable matters, fractionation sterol pattern and sterol compositions of the each fraction of the oil were compared in the oil extracted by the three different extraction methods, that is, pressure extraction of roasted seed (RTP), acetone extraction of roasted seed(RTE) and acetone extraction of raw seed(RWE). The amount of unsaponifiable in RWE oil was silghly higher as 31.8mg per 1mg drying oil than that in RTP oil of 26.1mg. Sesame oils from three different extraction methods were found to contain $0.26{\sim}0.32%$ free, $0.23{\sim}0.42%$ bound, and $0.49{\sim}0.64%$ total sterol. The content of free sterol in RWE oil was higher as 0.32% than that in RTE and RTP oil of 0.26%, and that of sterylglycoside in RTE oil was lower as 0.12% than that in RTP and RWE oil of 0.23%, but that of sterylester was a little difference. The unsaponifiable matter from fractionation sterol in sesame oil by three different extraction methods was fractionated into less polor compounds, 4,4-dimethyl-, 4-monomethyl-, 4-desmethylsterol fraction by thinlayer chromatography, and sterol composition of 4-desmethylsterol fraction was analyzed by gas liquid chromatography. The major sterols were campe-, stigma-, sito-, and ${\Delta}^5-avenasterol$, but, specially, unknown sterol(RRT:1.35) was found as $23.5{\sim}26.4%$ in total sterols, The content of sitosterol, ${\Delta}^5-avenasterol$, campesterol and stigmasterol were $59.9{\sim}60.3%,\;8.1{\sim}11%,\;16.1{\sim}18.4%,\;11.6{\sim}12.8%$ of the total sterol in free sterol fraction, $37.3{\sim}46.9,\;11.6{\sim}14.2,\;6.6{\sim}9.0$, and $6.1{\sim}8.0%$ of the total sterol in sterylglycoside fraction, $55.9{\sim}59.9,\;9.2{\sim}11.4,\;17.1{\sim}18.9$, and $11.8{\sim}13.7%$ of the total sterol in sterylester fraction, and $39.3{\sim}42.9,\;13.0{\sim}17.2,\;9.1{\sim}11.0$ and $7.4{\sim}11.5%$ of the total sterol in total sterol fraction. But the effect of oil extraction methods on sterol composition in sesame oil were hardly found.