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.
Vegetable seed oils (VSOs) have been extracted and used not only as ingredients in food and as sources of dietary lipids, but also as sources of nutraceuticals used to overcome the various oxidative stresses that contribute to the development of diseases, including cancer and other chronic conditions. The chemical compositions and oxidative stabilities of various VSOs were therefore investigated; samples were stored for 35 d, with each oil having been tested under O2 exposure, sealed from O2 exposure and sealed from O2 exposure while containing O2 scavengers. Oxidative stability was evaluated by peroxide value (POV), p-anisidine value (p-AnV), iodine value (IV), and thiobarbituric acid (TBA) value. Perilla seed and flaxseed oil were mostly composed of linolenic acid (45.5% and 59.7%, respectively), whereas pine seed oil was mostly composed of linoleic acid (48.3%). Meanwhile, camellia seed and olive oils contained 80% oleic acid, which correlated strongly with oxidative stability. The POV, p-AnV, and TBA values were the highest under O2 exposure, and the lowest in the presence of O2 scavengers. These results indicate that VOS oxidative stability depends not only on storage conditions, but on unsaturated fatty acid profiles as well.
바이오디젤의 저온유동성과 산화안정성은 주로 녹는점이 높은 포화 및 불포화 지방산 메틸에스테르의 함량에 의해 좌우된다. 본 연구는 동물성 유지인 우지 유래 바이오디젤에 요소를 첨가하여 포화지방산 메틸에스테르 함량을 저감시켜 동물성 바이오디젤의 저온유동성 개선과 포화지방산 메틸에스테르 함량이 저감된 동물성 바이오디젤을 식물성 바이오디젤에 혼합함으로써 식물성 바이오디젤(유채유, 폐식용유, 대두유 및 동백유)의 저온유동성을 개선하기 위해 수행 되었다. 연구결과, 동물성 바이오디젤의 포화도 저감을 통해 저온필터막힘점을 최대 –15℃까지 낮추었고, 포화도가 저감된 동물성 바이오디젤을 식물성 바이오디젤과 혼합함으로서 식물성 바이오디젤의 저온필터막힘점을 -10 ~ -18℃까지 낮출 수 있었다. 본 연구를 통해 동·식물성 유지 유래 바이오디젤의 저온특성을 개선함으로써 국내 겨울철 환경조건에서 연료유로 적용 가능성을 증대할 것으로 기대한다.
The biodiesel production characteristics in a pulsed-corona plasma reactor has been investigated through parametric tests. Transesterification of rapeseed oil together with camelina oil was done with the change of such variables as voltage of power, molar ratio, KOH catalyst and temperature. The energetic electrons emitted from pulsed-corona plasma has contributed to the enhancement of yield on rapeseed oil in short time (15 min). The higher yield on camelina oil was observed in 5 min. The optimal parameters were shown as the voltage of 23 kV, the molar ratio of 5/1, the content of KOH catalyst of 0.6 wt% and the temperature of 28℃ under the rotating rate of spark gap of 900 rpm.
The transesterification of rapeseed oil, soybean oil, and mixed fat were conducted at 65℃ with Al2O3-supported CaO, 0.8 wt% KOH, 1 wt% NaOH and mixed catalyst. The overall conversion(%) of rapeseed oil indicated to be 96% at the 12:1 molar ratio of methanol to oil, 8 wt% CaO and 2 wt% water. The pH ranges of biodiesel for mixed fat using four catalysts and for three fats using 8wt% CaO were 7.3-9.1, 7.3-7.5, respectively. The volumes of water needed to wash biodiesel from rapeseed oil using 0.8 wt% KOH and 8 wt% CaO were 15 mL and 3 mL.
The transesterification of vegetable oils into Biodiesel at 60℃ was performed on the rotary viscometer. The overall yield(%) of fatty acid methyl ester from canola oil at optimum conditions was 95%. The viscosities of fatty acid methyl esters were predicted by Orrick and Erbarr's model. The overall yield increased as the viscosities of fatty acid methyl esters decreased. The limiting molar ratio of methanol to oil appeared to be 1:5. The content of sodium hydroxide as the optimum catalyst appeared to be 0.5wt%.
Bio-diesel as fatty acid methyl ester was derived from such oils as soybean, peanut and canola oil by lipase catalyzed continuous trans-esterification. So the activation of lipase(Novozym - 435) was kept to be up to 4:1, the limiting molar ratio of methanol to oil under one-step addition of methanol due to the miscibility of oil and methanol through the static mixer for 4hrs and the elimination of glycerol on the surface of lipase by 7wt% silica gel. Therefore the overall yield of fatty acid methyl ester from soybean oil appeared to be 98% at 50·C of reaction temperature under two-steps addition of methanol with 2×2:1 of methanol to oil molar ratio at an interval of 5.5hrs, 7wt% of lipase, 24 number of mixer elements, 0.2ml/min of flow rate and 7wt% of silica gel.
The natural antioxidant such as e-tocopherol and synthetic antioxidant BHT were used to compare antioxidative effects of those antioxidants from the physico-chemical properties and fatty acid composition changes in the soybean oil due to number of frying. The composition of frying oil were consisted of a group(Fresh oil), B gorup(Fresh oil added with 0.05% α-tocopherol), C group(Fresh oil added with 0.2% α-tocopherol), D group(Fresh oil added with 0.1% BHT), E group(Tocopherol removed oil from oil by active alumina column chromatography The results obtained were as follws : 1. The color was determined by the Lovibond colorimeter color intensity increased number of frying oil. 2, The acid value, TBA value and Carbonyl value were increased number of frying oil. 3. Natural antioxidants less effective than BHT but effect of α-tocopherol was very similar to that of BHT. 4. The order of antioxidative effect was 0.1% BHT, 0.2% α-tocopherol, 0.05% α-tocopherol, fresh oil, tocopherol remove oil.
The purpose of the study was to find an effect of phospholipid-free vegetable oils on the serum lipids and proteins of Sprague-Dawley rats. All experimental rats were fed ad libitum for 60days with the mixture of starch: casein: salt mixture: vitamin mixture (60:18:4:1) and at the same time fed administratively with 1 ml of soybean oil, corn oil and sesame oil bought in market as source of phospholipid-free vegetable oils(PFVO) and those extracted directly by and oil press as source of phospholipid-containing vegetable oils(PCVO) respectively. At the last day of experimental period, the rats were fasted for 12 hours and decaptitated to collect blood for analysis of serum lipid and protein. The results of this study were summerized as follows. 1. The supplementation of dietary phospholipid decrease food efficiency ratio and the growth rate of experimental rats. 2. The supplementation of dietary phospholipid improve correlation coefficient of body weight and organ weights. 3. The supplementation of dietary phospholipid increase the level of serum phosphatidylethanolamine. Therefore, I think that we must eat dietary phospholipid unpurified from vegetable oil to prevent development of atherosclerosis and fat liver.
No difference was observed on autoxidative stability of triacylglycerols before and after randomyl interesterification. It indicate that randomization of the glyceride composition has no significant effect on the autoxidative stability. On the other hand, the autoxidation of randomyl interesterified vegetable oil was accelerated, caused mainly by decrease of tocopherols during the series of interesterification procedures.
The effects of procedures for preparation of fatty acid methyl esters for gas chromatography were investigated. A quantitative comparison of four procedures for the preparation of the fatty acid methyl esters from Korean sesame seed lipids which can be representative of fatty acid ranges of Korean vegetable oils has been made. The procedures employed were BF3-methanol, HCI-methanol, sodium methoxide-methanol, and tetramethylammonium hydroxide-methanol. Twelve fatty acids ranged from 14:0 to 24:0 were identified in the lipids from Korean white and black sesame seeds. All four procedures gave similar results for the fatty acids, 16:0, 18:0, 18:1, 18:2, and 18:3 present in the range of 1~44% but only in the HCI-methanol procedure, the fatty acids, 16:1, 20:0, 22:0, 24:0 present in the range of 0.02~1% showed the lowest values. When using tetramethylammonium hydroxide-methanol procedure for determination of total fatty acid composition from white and black sesame seed lipids, unsaponifiable matters including sesamol, sesamolin and sesamin present in the seed lipids are not removed from the resulting reaction mixture. Thus the transesterification mixture is used without further treatment for injection into the gas chromatography. However, the gas chromatographic analysis of the transesterification mixture showed that the unsaponifiable matters had no effect on the fatty acid composition of the seed lipids. From the results, it appears that the BF3-methanol, sodium methoxide-methanol and tetramethylammonium hydroxide-methanol procedures can be used to prepare fatty acid methyl esters from Korean vegetable oils. Among the methods, the tetramethylammonium hydroxide-methanol procedure, which give total fatty acid composition, glyceride fatty acid composition and composition of free fatty acids present, appears to be a simple, convenient and quantitative procedure and applicable to samples containing broad ranges of fatty acids.
본 연구는 주요 구성지방산이 Oleic acid인 유채유, 동백유, 올리브유와 Palmitic acid가 주요 구성 지방산인 팜유를 기준으로 중량비로 혼합하여 지방산 조성 및 물성변화를 관찰 하였다. 지방산 조성의 변화를 전체적으로 살펴보면 50:50(w/w)비율에서는 Oleic acid은 유채유와 대두유의 혼합 시 42.8%로 가장 낮았고 동백유와 유채유의 혼합비율에서 72.1%로 가장 높았다. 75:25(w/w)유채유와 대두유 혼합비율에서 가장 낮았고 동백유와 올리브유의 혼합비에서 가장 높았다. 팜유를 기준으로 식물성 유지를 혼합하였을 시에는 다른 유지와 혼합 후 총 포화지방산은 감소하였다. 혼합 후 지방산 조절을 통한 산화안정성 및 저온에서의 유동성 개선이 기대 된다. 혼합 후 동백유 〉 올리브유 〉 유채유 순으로 산가 안전화 경향을 보였으며 이는 Oleic acid 함량에 따라 기인한 것으로 보인다. 또한 혼합을 통한 산화안정성을 개선시킬 수 있을 것으로 판단되며, 색도는 비율 및 유지에 따른 유의적인 변화를 보이지는 않았으나 바이오디젤 생산 정제공정에 있어서 혼합비율 조절에 따른 정제비용 절감이 기대 된다. 본 연구를 통하여 유지간 혼합에 의한 특성변화를 확인하고, 혼합유의 원료 다양성 확보 및 품질개선을 위한 정보를 얻어 향후 연구수행의 기초자료로 활용이 가능할 것으로 생각된다.