Synthetic methods to obtain conjugated linoleic acids (CLAs) by catalysis – A review

Salamon, R. V.; Vargáné-Visi, É.; András, Cs. D.; Kiss, Zs.; Csapó, J.

doi:10.1556/aalim.2014.0006

Cited by 12 publications

(10 citation statements)

References 25 publications

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“…This requirement of halfhydrogenated intermediates led to the formation of unwanted hydrogenated by-products. 16 Though the production of CLAs by heterogeneous catalysts without hydrogen is a difficult and complicated process, it can reduce the production of unwanted by-products. Therefore, Bernas et al 17 further developed an isomerization catalyst; they used Ru/C catalyst for the isomerization of linoleic acid without the use of H 2 , but the CLA production rate was only 23 g(CLA) per g(metal) per h. Philippaerts et al 18 described H 2 -free production of CLA using Ruloaded zeolite catalysts with high CLA production rate; however, the process needed negative pressure during the reaction itself and the catalysts synthesis process was complex.…”

Section: Introductionmentioning

confidence: 99%

Revealing ruthenium and basicity synergetic effects in Ru–MgAl catalysts for isomerization of linoleic acid to conjugated linoleic acid

et al. 2017

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Ru-MgAl catalysts were prepared by co-precipitation at different pH values (x ¼ 7-12), with the aims of investigating the effect of pH on their catalytic performance for isomerization of linoleic acid to conjugated linoleic acid and of understanding the relationship of basicity site and ruthenium activity site.The results showed that strong basicity and highly dispersed ruthenium may be the active sites for linoleic acid isomerization. Only if all three conditions, i.e., high Ru dispersion, appropriate SMSI effect and high number of strong basicity sites, are fulfilled can highly effective active sites be formed for the isomerization of linoleic acid to conjugated linoleic acid. A possible reaction mechanism for the isomerization was also proposed.

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Section: Introductionmentioning

confidence: 99%

Revealing ruthenium and basicity synergetic effects in Ru–MgAl catalysts for isomerization of linoleic acid to conjugated linoleic acid

et al. 2017

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“…Isomerization of unsaturated fatty acid derivatives may have two different objectives. On the one hand, the isomerization of linoleic acid derivatives to produce conjugated linoleic acids (CLA), 161,162 due to the interesting health benefits claimed for some of the conjugated isomers (Figure 4). The classical method involves reaction under strong basic conditions (KOH) in an organic solvent, such as ethylene glycol, at 180 °C, leading to more than 97% yield of CLA, with more than 92% yield of the two most interesting isomers, c9,t11 and t10,c12 (Figure 4).…”

Section: Isomerizationmentioning

confidence: 99%

Synthetic Transformations for the Valorization of Fatty Acid Derivatives

et al. 2017

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Oleochemistry is a growing field from the industrial point of view, and one of the basis for a more sustainable chemical production, less dependent of fossil sources. From this point of view, the development of selective and efficient synthetic transformations of triglycerides and fatty acids and esters is an active research field. This short review describes an overview of the most recent advances in the synthetic transformations of fatty acid derivatives into valuable chemicals. 1 Introduction 2 Triglycerides 2.1 Reactions on the ester group and multistep processes 2.2 Epoxidation 2.3 Ozonolysis 2.4 Cross metathesis 3 Reactions on the ester group of fatty acids and esters 3.1 Synthesis of free carboxylic acids 3.2 Synthesis of carboxylic esters 3.3 Reduction to alcohols and aldehydes 3.4 Synthesis of nitrogenated derivatives 4 Oxidation of Unsaturated Fatty acids and esters 4.1 Epoxidation and reactions of epoxides 4.2 Allylic oxidation 4.3 Synthesis of ketoderivatives 4.4 Oxidative cleavage 5 Addition reactions of unsaturated fatty acids and esters 5.1 Hydrogenation and hydroformilation 5.2 Cycloadditions and related reactions 5.3 Addition of carboxylic acids 5.4 Hydroalkylation 5.5 Radical additions 6 Other reactions of unsaturated fatty acids and esters 6.1 Cross metathesis 6.2 Isomerization 7 Conclusion and outlook

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“…In alkali isomerization, the positions of protons are changed along the hydrocarbon chain of LA to conjugated positions of the double bonds, that is, without methylene carbons between them . For this purpose, vegetable oils with a high LA proportion are heated at 180°C with a strong base as sodium or potassium hydroxide and ethylene glycol for a given period of time . However, the main problem in the alkali isomerization process is the difficulty to separate the homogeneous catalysts from the CLA products.…”

Section: Introductionmentioning

confidence: 99%

“…In contrast to the heterogeneous catalysis, microbiological methods possess a high specificity toward the production of bioactive CLA isomers, mainly toward the cis 9, trans 11‐CLA isomer . Unfortunately, the low conversion of LA to CLA and the long reaction times employed by the microbiological methods make them uncompetitive against alkali isomerization .…”

Section: Introductionmentioning

confidence: 99%

Synthesis of conjugated linoleic acid by microwave‐assisted alkali isomerization using propylene glycol as solvent

Silva‐Ramírez

Rocha‐Uribe

González‐Chávez

et al. 2016

Euro J Lipid Sci & Tech

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Conjugated linoleic acid (CLA) is a group of isomers of linoleic acid (LA) with a conjugated double‐bond system that occurs in trace amounts in natural oils. As result of the beneficial properties on the health, bioactive isomers of CLA (cis9,trans11‐CLA and trans10,cis12‐CLA) have been industrially produced by alkali isomerization of LA. A large amount of studies regarding the CLA production might be found; however, new approaches as the use of microwave irradiation have been recently suggested. Here, we develop an efficient and sustainable method to selectively produce bioactive CLA by microwave‐assisted isomerization of LA using propylene glycol as solvent. The investigated reaction variables were solvent/LA mass ratio (1:1–6:1), catalyst/LA mass ratio (0.25:1–0.6:1), temperature (160–180°C), catalyst type (KOH or NaOH), and reaction time. The results showed that: (i) KOH increased the production of conjugated trans‐trans isomers; (ii) a considerable reduction of propylene glycol on the reaction was possible using NaOH; and (iii) the reaction time was drastically reduced in comparison to conventional heating. Thus, the optimum conditions for the cis9,trans11‐CLA and trans10,cis12‐CLA production (91.21% in equimolar ratio) were: NaOH at a catalyst/LA mass ratio of 0.5:1 and solvent/LA mass ratio of 1:1 at 160°C during 4 min. Practical applications: CLA has been subject of growing interest in nutrition and the food industry due to its wide range of biological activities including anti‐carcinogenic and anti‐atherogenic properties. Here, the chemical synthesis of CLA by microwave‐assisted alkali isomerization was studied in order to lower the production costs by decreasing both, the propylene glycol content (the most expensive solvent used for this kind of reaction) and the reaction time. In comparison to conventional heating, reaction time was drastically reduced by employing microwave heating while the selective synthesis of cis9,trans11‐CLA and trans10,cis12‐CLA was achieved at low solvent conditions when the reaction conditions were optimized. In this sense, the methodology developed in this work could be used in order to obtain more efficiently and sustainably the bioactive forms of CLA, which in turn could be used in the manufacture of functional foods or dietary supplements. cis9,trans11‐CLA and trans10,cis12‐CLA were selectively synthetized through basic catalysis of linoleic acid in propylene glycol under microwave irradiation.

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Synthetic methods to obtain conjugated linoleic acids (CLAs) by catalysis – A review

Cited by 12 publications

References 25 publications

Revealing ruthenium and basicity synergetic effects in Ru–MgAl catalysts for isomerization of linoleic acid to conjugated linoleic acid

Revealing ruthenium and basicity synergetic effects in Ru–MgAl catalysts for isomerization of linoleic acid to conjugated linoleic acid

Synthetic Transformations for the Valorization of Fatty Acid Derivatives

Synthesis of conjugated linoleic acid by microwave‐assisted alkali isomerization using propylene glycol as solvent

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