• Journal of the Korean Society of Food Science and Nutrition
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• v.45 no.9
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• pp.1351-1357
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• 2016

Green tea (Camellia sinensis) seed extract (GTSE) was prepared under various pretreatment conditions and used to investigate its extraction yield and anti-yeast activity. Anti-yeast activity of GTSE from seeds with or without the coats was the same, whereas the extraction yield was slightly higher in extract from seeds without the coat. Anti-yeast activity of GTSE from seeds with different water contents or particle sizes was the same, whereas the extraction yield was highest in extract from seeds with 7.3% moisture or a smaller particle size. Anti-yeast activity of defatted green tea seed extract (DGTSE) was the same as that of GTSE. Extraction yield was higher in DGTSE from defatted seeds by the oil press machine compared to hexane extraction. Defatted green tea seed (DGTS), a by-product from the oil extraction process, is a good natural source of anti-yeast preservative. The extraction yield and anti-yeast activity of DGTSE were investigated using various extraction solvents, temperatures, and times. The results show that water was an economic extraction solvent, and anti-yeast activity of DGTSE was unstable at $90^{\circ}C$. These results suggest that water, extraction temperature of $50^{\circ}C$, and extraction time of 4 h were the most efficient for extraction of anti-yeast compounds from DGTS.

• Journal of the Korean Applied Science and Technology
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• v.8 no.1
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• pp.27-34
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• 1991

동백종실유(冬栢種實油)에서 컬럼크로마토그래피로 지질(脂質) 성분(成分)을 상호(相互) 분리(分離)하였다. 여기서 얻은 트리글리세리드의 일부(一部)를 취하여 알칼리로 가수분해(加水分解)하거나 또는 pancreatic lipase로 가수분해(加水分解) 하여, 트리글리세리드의 구성(構成) 지방산(脂肪酸) 또는 1, 3- 위치(位置)와 2-위치(位置)에 급합(給合) 한 지방산(脂肪酸) 조성(組成)을 조사(調査)하였다. 나머지 트리글리세리드는 16% $AgNO_3$ TLC로 이중결합선(二重結合敾)별로 나누었으며, 이렇게 나누어진 분획(分劃)을 다시 HPLC로 PN별로 재분획(再分劃) 하였다. 여기서 얻어진 획분(劃分)들 중 PN이 같은 것은 모두 모아서 알칼리 가수분해(加水分解)로 PN의 총지방산(總脂肪酸) 조성(組成)을, pancreatic lipase로 1,3 위치(位置)에 결합선(結合敾)한 지방산(脂肪酸)의 조성(組成)을 조사(調査) 하였다. 여기서 얻어진 결과(結果)로 부터 구성(構成) 트리그리셀리드 분자종(分子種)을 산출(算出)하였더니 다음과 같은 결과(算出)를 얻었다. 1) 종실유(種實油)는 투명(透明)한 액체(液體)로 그 함량(含量)이 73.5%였으며, 그 중 트리글리세리드가 94.8%, 극성(極性) 지질(極性)이 2.0%, 탄화(炭化) 수소(水素)가 1.8%였다. 2) $AgNO_3$-TLC로 트리글리세리드를 분획(分劃)하였더니 5개의 획분(劃分)을 얻었으며, 대부분(大部分)의 트리글리세리드가 이중(二重) 결합선(結合敾) 3${\sim}$5개인 band 2와 band 3에 80% 이상 존재(存在)하였다. 3) $AgNO_3-TLC$에서 얻은 각 획분(劃分)은 모두가 HPLC상에서 PN 46, 48 및 50으로 나누어졌으며 전체(全體) 분획(分劃)에서 PN 48이 78.13%로 제일 많았으며, 다음으로 PN 50이 12.04%였으며, PN 46이 9.83%였다. 4) 전체(全體) 트리글리세리드 분자종(分子種) 중에서 0.1mol% 이상을 차지하고 있는 분자종(分子種)이 43종(種)이었으며, OOO와 POO가 각각 39.8mol%와 25.8mol%로 제일 많았으며, 그 다음으로 OPO가 5.5 mol%, OOL가 4.8 mol%, POS가 3.9mol%, SOO가 3.5mol%. POL이 3.0mol%였다. 또 동백종실유(冬栢種實油)에 존재(存在)하는 트리글리세리드의 분자종(分子種)의 조성(組成)은 1,3-random, 2-random 분포설(分布說)에 따라 구성(分布說)되어 있었다.

• Journal of the Korean Applied Science and Technology
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• v.31 no.1
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• pp.113-119
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• 2014

The compositions of saturated and unsaturated fatty acids in biodiesel feedstocks are important factors for biodiesel properties including low-temperature fluidity and oxidative stability. This study was conducted to improve low-temperature fluidity of biodiesel by reducing total saturated FAME (fatty acid methyl ester) in animal fat biodiesel fuels via urea-based fractionation and by mixing plant biodiesel fuels (rapeseed-FAME, waste cooking oil-FAME, soybean-FAME, and camellia-FAME) with enriched-polyunsaturated FAME derived from animal fat biodiesel. Our results showed that the reduction of total saturated FAME in animal fat biodiesel lowered CFPP (Cold Filter Plugging Point) to $-15^{\circ}C$. Mixing plant biodiesel fuels with the enriched-polyunsaturated FAME derived from animal fat biodiesel lowered CFPP of blended biodiesel fuels to $-10{\sim}-18^{\circ}C$.

• Korean Journal of Food Science and Technology
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• v.47 no.1
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• pp.103-110
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• 2015

In this study, we evaluated the fatty acid composition and physiological activities of oils extracted from eight types of seeds, pepper (Capsicum annuum L.), green tea (Camellia sinensis L.), perilla (Perilla frutescens var. japonica Hara), peanut (Arachis hypogaea L.), cotton (Gossypium indicum LAM.), sesame (Sesamum indicum L.), walnut (Juglans regia L.), and safflower (Carthamus tinctorius L.). The composition and quality analysis showed that the oils were potentially suitable for foo-grade applications. The composition analysis showed that the oils were mostly composed of unsaturated fatty acids including linoleic acid and oleic acid. In 3T3-L1 adipocytes, green pepper, perilla, and peanut seed oils inhibited lipid accumulation, and green pepper, perilla, peanut, sesame, walnut, and safflower seed oils induced leptin secretion. These results show that the inhibitory effect of edible seed oils on lipid accumulation, and induction of leptin secretion may be useful for obesity management.