Technological Aspects of Chemoenzymatic Epoxidation of Fatty Acids, Fatty Acid Esters and Vegetable Oils: A Review

Milchert, Eugeniusz; Malarczyk, Kornelia; Kłos, Marlena

doi:10.3390/molecules201219778

Cited by 61 publications

(47 citation statements)

References 78 publications

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“…The olefins Ole and LinOle are model substrates for fatty‐acid methyl esters (FAMEs), which are produced from vegetable oils by transesterification . Epoxidized FAMEs have widespread use, for example, as solvents, lubricants, PVC stabilizers and plasticizers, and as intermediates in the production of polyurethane polyols, cosmetics, and pharmaceuticals . Traditionally, at the industrial level, plant oils and their derivatives are epoxidized under homogeneous conditions by using the Prilezhaev reaction, involving peracids generated in situ by the reaction of organic acids with hydrogen peroxide in the presence of a mineral‐acid catalyst , , .…”

Section: Resultsmentioning

confidence: 99%

“…Epoxidized FAMEs have widespread use, for example, as solvents, lubricants, PVC stabilizers and plasticizers, and as intermediates in the production of polyurethane polyols, cosmetics, and pharmaceuticals . Traditionally, at the industrial level, plant oils and their derivatives are epoxidized under homogeneous conditions by using the Prilezhaev reaction, involving peracids generated in situ by the reaction of organic acids with hydrogen peroxide in the presence of a mineral‐acid catalyst , , . Environmental and safety concerns associated with this stoichiometric process have motivated the search for alternative catalytic methods that employ more convenient oxidants.…”

Section: Resultsmentioning

confidence: 99%

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Chemistry and Catalytic Performance of Pyridyl‐Benzimidazole Oxidomolybdenum(VI) Compounds in (Bio)Olefin Epoxidation

et al. 2017

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The chemistry and catalytic performance of the dichlorido complex [MoO2Cl2(pbim)] (1) [pbim = 2‐(2‐pyridyl)‐benzimidazole] in the epoxidation of olefins is reported. Complex 1 acts as a precatalyst and is more effective with tert‐butylhydroperoxide (TBHP) as the oxidant than with aq. hydrogen peroxide: the cis‐cyclooctene (Cy) reaction with TBHP gave 98 % epoxide yield at 70 °C/24 h. Catalyst characterization showed that 1 is transformed in situ to the oxidodiperoxido complex [MoO(O2)2(pbim)] (2), with H2O2 and a hybrid molybdenum(VI) oxide solid formulated as [MoO3(pbim)] (3) with TBHP. The hybrid material 3 was prepared on a larger scale and explored for the epoxidation of the biorenewable olefins methyl oleate, methyl linoleate, and (R)‐(+)‐limonene. With TBHP as the oxidant, 3 acts as a source of soluble active species of the type 2. A practical method for recycling oxidodiperoxidomolybdenum(VI) catalysts for the Cy/TBHP reaction is demonstrated by using an ionic liquid as the solvent for the molecular catalyst 2.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Chemistry and Catalytic Performance of Pyridyl‐Benzimidazole Oxidomolybdenum(VI) Compounds in (Bio)Olefin Epoxidation

et al. 2017

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“…proved that hydrogen peroxide deactivate oxalate oxidase during the oxidation of oxalate to carbon dioxide. In addition, Milchert et al . reviewed the effect of different parameters on chemoenzymatic epoxidation process of vegetable oils.…”

Section: Oleochemicals Overviewmentioning

confidence: 99%

Epoxidized vegetable oil and bio‐based materials as PVC plasticizer

Hosney

Nadiem

Ashour

et al. 2018

J of Applied Polymer Sci

122

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Phthalate esters received a considerable attention owing to its various applications and the harmful health effects resulting from phthalate exposure; thus, finding an alternative to phthalate derivatives became a necessity. Phthalate esters are commonly used as plasticizer in polymer formulation; in particular for poly(vinyl chloride) (PVC) formulation. According to the researches in the last 18 years, epoxidized vegetable oils are one of the alternatives that are strongly encouraged to substitute phthalate esters since they were proven to be valid in various applications, eco-friendly and sustainable resource. However, most of the production practices for epoxidized vegetable oil are via conventional epoxidation that concentrates on a catalyst that is homogeneous and non-reusable. This type of catalyst, however, causes several problems later in the process. Therefore, the selective epoxidation of vegetable oils process requires new catalytic systems that are more aligned with the green chemistry principles. This article reviews the harmful health effects associated with the exposure to phthalate esters products, explains the usage of oleochemicals resources as a substitute to phthalate esters and describes different approaches for the epoxidation of vegetable oils. Finally, it draws attention to the usage of epoxy and bio-based compounds as plasticizers in PVC manufacturing.

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“…[7] One challenge to be faced in the synthesis of epoxidized esters is the hydrolytic activity of the enzymes, which leads to epoxidized fatty acids in the presence of water.T herefore, if epoxidized esters such as epoxidized vegetable oils are desired, particulara ttention has to be paid to the exclusion of trace amounts of water.Very recently,w er eported that lipase Gf rom Penicillieum camembertii exhibited no activity towards triglycerides,w hich made it ap romising catalystf or the direct epoxidation of epoxidizedt riglycerides. [8] Unfortunately,h owever,l ipase Gw as not very robust under the reactionc onditions, which limited its practical applicability.I nspired by av ery recent contribution, [9] we decided to evaluate some natural deep eutectic solvents (DESs) as stabilizers for lipase G. In af irst set of experiments,w ecompared different DESs as reaction media for the chemoenzymatic epoxidation of glyceryl trioleate (GT) to epoxidizedg lyceryl trioleate (EGT) (Figure 1). Notably,t he acid number of the GT used in this study was comparably high (1 mg (KOH) per gram of GT corresponding to an oleic acid concentrationi nG To fc a.…”

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confidence: 99%

Deep Eutectic Solvents Enable More Robust Chemoenzymatic Epoxidation Reactions

et al. 2017

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Ac hemoenzymatic method for the production of epoxidized vegetable oils was developed. The unique combination of the commercial lipase Gf rom Penicillieum camembertii with certain deep eutectic solvents enabled the efficient production of epoxidized vegetable oils.Epoxidized vegetable oils are promising substitutes for phthalates as plasticizers, [1] lubricants, [2] and coatings. [3] Traditional synthetic routes for the epoxidation of unsaturated triglycerides entailt he stoichiometric use of peracids such as peracetic acid under acidic reactionc onditions. The challenges of these methods reside with the rather corrosiver eaction conditions, their poor atom efficiency,t he relativelyh arsh reaction conditions, andthe considerable amounts of waste generated.The in situ generation of the reactive peracidf rom catalytic amountso fc arboxylic acids and hydrogen peroxide (H 2 O 2 )b y using hydrolases as catalysts represents av ery promising solution to the aforementioned challenges (Scheme 1). [4] First reported in 1990 by Bjçrkling and co-workers, [5] this perhydrolase activity has found widespread application in the chemoenzymatic synthesis of epoxides [6] and lactones. [7] One challenge to be faced in the synthesis of epoxidized esters is the hydrolytic activity of the enzymes, which leads to epoxidized fatty acids in the presence of water.T herefore, if epoxidized esters such as epoxidized vegetable oils are desired, particulara ttention has to be paid to the exclusion of trace amounts of water.Very recently,w er eported that lipase Gf rom Penicillieum camembertii exhibited no activity towards triglycerides,w hich made it ap romising catalystf or the direct epoxidation of epoxidizedt riglycerides. [8] Unfortunately,h owever,l ipase Gw as not very robust under the reactionc onditions, which limited its practical applicability.I nspired by av ery recent contribution, [9] we decided to evaluate some natural deep eutectic solvents (DESs) as stabilizers for lipase G. In af irst set of experiments,w ecompared different DESs as reaction media for the chemoenzymatic epoxidation of glyceryl trioleate (GT) to epoxidizedg lyceryl trioleate (EGT) (Figure 1). Notably,t he acid number of the GT used in this study was comparably high (1 mg (KOH) per gram of GT corresponding to an oleic acid concentrationi nG To fc a. 19 mm). The presence of free oleic acid in the starting material made any external addition of other (fatty) acids unnecessary.Pleasingly,D ESs had av ery beneficial effect on the overall activity.T hus, the rate of formation of EGT increased more than 22-fold relative to the rate obtained under aqueous reaction conditions (7 mm h À1 )t o1 72 mm h À1 by using choline chloride (ChCl)/ xylitola st he reactionp hase. Furthermore, the re-Scheme1.Chemoenzymaticepoxidation of glyceryltrioleate. Figure 1. Time course of the chemoenzymatic epoxidation of GT to EGT in different reaction media. General conditions:reactions were performed in a1 0mLE rlenmeyer flask at 40 8Cfor 24 hw ith magnetic stirring (500 rpm).The...

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Technological Aspects of Chemoenzymatic Epoxidation of Fatty Acids, Fatty Acid Esters and Vegetable Oils: A Review

Cited by 61 publications

References 78 publications

Chemistry and Catalytic Performance of Pyridyl‐Benzimidazole Oxidomolybdenum(VI) Compounds in (Bio)Olefin Epoxidation

Chemistry and Catalytic Performance of Pyridyl‐Benzimidazole Oxidomolybdenum(VI) Compounds in (Bio)Olefin Epoxidation

Epoxidized vegetable oil and bio‐based materials as PVC plasticizer

Deep Eutectic Solvents Enable More Robust Chemoenzymatic Epoxidation Reactions

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