Enzymatic acidolysis of sunflower oil with a palmitic–stearic acid mixture

The main methods of obtaining fractionated oils and fats have been analysed. They involve three essentially different processes of fractionation of acylglycerols: dry fractionation, aqueous fractionation with a detergent, and solvent fractionation. Considerable attention has been paid to determining the conditions for fractionation of sunflower oil modified in its fatty acid composition. It has been emphasised that using stearic sunflower oil free from trans fatty acids as a source of fats is a topical task. The practical importance of complex research on fractional crystallisation of stearic sunflower oil has been substantiated. The experiments have allowed establishing the fatty acid and triacylglycerol composition of the oil of the new line of sunflower seeds of the saturated type Х114В (stearic type). The structure of its acylglycerols has been mathematically determined. Data have been obtained that besides the increased stearic acid content (9.1% of the total fatty acids), the oil under study also contains a significant amount of the disaturated–monounsaturated fraction of acylglycerols (6.16%). The method of fractionating sunflower oil of the stearic type, which has been scientifically substantiated, involves one-stage fractional crystallisation from the melt. The conditions of fractional crystallisation have been experimentally established: the crystallisation temperature range (+6 – +9°С), the crystallisation time (38 days), and the cooling rate (≈0.0051°С/s). The target fraction of sunflower oil of the stearic type has been obtained. It differs from the original oil in its fatty acid and acylglycerol composition. The yield of this oil fraction was 24.57%. It has been found that the fatty acid composition of this fraction has a content of palmitic acid increased by 0.9% and that of stearic acid higher by 3.3%, while its linoleic acid content decreased to 41.9%. The total amount of saturated fatty acids in the target fraction sample is 19.8% of all fatty acids. It has been found that the proportion of disaturated–monounsaturated acylglycerols in the target fraction increases by 3.27%. The resulting target fraction will be useful in flour and confectionery technologies as a substitute for fats containing trans fatty acids

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Structuring of sunflower oil by stearic acid derivatives: Experimental and molecular modelling studies

Food Chemistry ◽

10.1016/j.foodchem.2020.126801 ◽

2020 ◽

Vol 324 ◽

pp. 126801 ◽

Cited By ~ 1

Author(s):

Zhaojing Jiang ◽

Xuanxuan Lu ◽

Sheng Geng ◽

Hanjun Ma ◽

Benguo Liu

Keyword(s):

Stearic Acid ◽

Molecular Modelling ◽

Sunflower Oil ◽

Molecular Modelling Studies ◽

Modelling Studies

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Formulation of Pickering sunflower oil-in-water emulsion stabilized by chitosan-stearic acid nanogel and studying its oxidative stability

Carbohydrate Polymers ◽

10.1016/j.carbpol.2019.01.008 ◽

2019 ◽

Vol 210 ◽

pp. 47-55 ◽

Cited By ~ 19

Author(s):

Majid Atarian ◽

Ahmad Rajaei ◽

Meisam Tabatabaei ◽

Afshin Mohsenifar ◽

Hojatolah Bodaghi

Keyword(s):

Stearic Acid ◽

Oxidative Stability ◽

Sunflower Oil ◽

Water Emulsion ◽

Oil In Water ◽

Oil In Water Emulsion

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THE NEW LINES OF SUNFLOWER WITH HIGH CONTENT OF STEARIC ACID IN SEED OIL

10.25230/conf11-2021-135-138 ◽

2021 ◽

Author(s):

Yu.V. Chebanova ◽

◽

T.A. Kovalenko ◽

Keyword(s):

Stearic Acid ◽

Helianthus Annuus ◽

Vegetable Oils ◽

Sunflower Oil ◽

Food Industry ◽

Seed Oil ◽

Food Products ◽

Inbred Lines ◽

The Other ◽

Helianthus Annuus L

There is a demand in the food industry for natural solid vegetable oils. The use of sunflower oil with a high content of stearic acid prevents its hydrogenation in the manufacture of food products. The development of new lines of sunflower (Helianthus annuus L.) with an increased content of stearic acid may increase the demand for sunflower oil, a useful analogue of solid vegetable oils for special food purposes. We identified two inbred lines with a high content of stearic and oleic acids from a source with a high content of these acids, one of which, I5HSHO-1, is one-headed, the other, I5HSHO-2v, is many-branched, as well as two one-headed lines with high content of stearic acid on the linoleic background (I5HSLO-1, I5HSLO-2).

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Kinetics of Melt Crystallization of a Sunflower Oil-Based Polyunsaturated Fatty Acid Mixture

Chemical Engineering & Technology ◽

10.1002/ceat.201200524 ◽

2013 ◽

Vol 36 (7) ◽

pp. 1225-1230 ◽

Cited By ~ 2

Author(s):

S. Dasgupta ◽

P. Ay ◽

R. Kommolk ◽

S. Xu

Keyword(s):

Fatty Acid ◽

Polyunsaturated Fatty Acid ◽

Sunflower Oil ◽

Fatty Acid Mixture ◽

Acid Mixture ◽

Melt Crystallization ◽

Kinetics Of

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Wear Properties of Wood-plastic Composites Pretreated with a Stearic Acid-palmitic Acid Mixture before Exposure to Degradative Water Conditions

BioResources ◽

10.15376/biores.13.2.3817-3831 ◽

2018 ◽

Vol 13 (2) ◽

Cited By ~ 3

Author(s):

Liangpeng Jiang ◽

Chunxia He ◽

Xiaolin Li ◽

Jingjing Fu

Keyword(s):

Stearic Acid ◽

Palmitic Acid ◽

Acid Mixture ◽

Wear Properties ◽

Wood Plastic Composites ◽

Plastic Composites ◽

Water Conditions

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Modification of Palm Mid Fraction with Stearic Acid by Enzymatic Acidolysis Reaction

Journal of the Korean Society of Food Science and Nutrition ◽

10.3746/jkfn.2009.38.4.479 ◽

2009 ◽

Vol 38 (4) ◽

pp. 479-485 ◽

Cited By ~ 1

Author(s):

Mi-Sun Jeon ◽

Yun-Jeung Lee ◽

Ji-Hyun Kang ◽

Jeung-Hee Lee ◽

Ki-Teak Lee

Keyword(s):

Stearic Acid ◽

Enzymatic Acidolysis ◽

Acidolysis Reaction

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The effects of fish oil supplementation on rumen metabolism and the biohydrogenation of unsaturated fatty acids in beef steers given diets containing sunflower oil

Animal Science ◽

10.1079/asc41920361 ◽

2005 ◽

Vol 80 (3) ◽

pp. 361-367 ◽

Cited By ~ 48

Author(s):

M. R. F. Lee ◽

J. K. S. Tweed ◽

A. P. Moloney ◽

N. D. Scollan

Keyword(s):

Fatty Acid ◽

Linoleic Acid ◽

Stearic Acid ◽

Fish Oil ◽

Sunflower Oil ◽

Vaccenic Acid ◽

Ruminal Ph ◽

Chain Pufa ◽

N Concentration ◽

Long Chain

AbstractDuodenally and ruminally fistulated steers were offered grass silage and one of three concentrates at a ratio of 60: 40 (forage: concentrate on a dry-matter basis) : F0, F1 or F4 at 14 g/kg live weight. The concentrates were designed to be iso-lipid and to provide the same amount of sunflower oil but increasing amounts of fish oil : 0, 1 and 4 g per 100 g, respectively. Ruminal characteristics were measured along with fatty acid intakes and duodenal flows to determine the effect of fish oil on : ruminal pH, ammonia-N concentration, volatile fatty acid (VFA) concentration and polyunsaturated fatty acid (PUFA) metabolism. Fish oil had no significant effect on ruminal pH, ammonia-N concentration or the molar proportions of the major VFA, although total VFA concentration was significantly reduced at the highest level of fish oil inclusion. Fish oil significantly increased the flow of long chain PUFA, total conjugated linoleic acid and vaccenic acid to the duodenum and decreased the flow of stearic acid. Biohydrogenation, as determined by the net loss of fatty acid between the mouth and duodenum, of oleic and linolenic acid was not affected by fish oil inclusion and averaged 0·64 and 0·92, respectively. There was a small increase in the biohydrogenation of linoleic acid with increasing fish oil from 0·89 to 0·92 (P< 0·01) on F0 and F4, respectively. Biohydrogenation of the long chain PUFA C20 : 5(n-3) and C22 : 6(n-3) increased from 0·49 and 0·74 to 0·79 and 0·86 (P< 0·01), respectively when fish oil in the concentrate increased from 1 to 4 g per 100 g. The net effect of fish oil on lipid metabolism appears to inhibit the transition of vaccenic acid to stearic acid in the rumen resulting in a build up of this intermediate in the biohydrogenation pathway of C18 PUFA.

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