Enzymatic synthesis of glycamide surfactants by amidification reaction

Efficient and Versatile Flow Synthesis of New Nonionic Glucamide Surfactants

Surfactants are virtually used across all industries where they can fulfill a multitude of roles, such as detergents, emulsifiers, and dispersants, as well as wetting, foaming, and flotation agents. N-Acyl-N-alkyl-d-glucamides are nonionic surfactants that can be synthesized from inexpensive natural resources. They have a broad range of hydrophilic-lipophilic balance (HLB) values, depending on the length of the alkyl chain. This chemical diversity and versatility allow customization of surfactant properties, making these chemicals useful for a diverse range of industrial purposes. In this work, six N-acyl-N-alkyl-d-glucamides have been prepared by exploiting immobilized scavengers and reagents in a flow-batch mode. Moreover, the interfacial properties (both surface and interfacial tensions) of two selected glucamide-based surfactants were evaluated.

Enzyme Engineering for High-Yielding Amide Formation: Lipase-Catalyzed Synthesis of N-Acyl Glycines in Aqueous Media

Amide syntheses remain a key challenging green chemistry reaction. For instance, green synthesis of N-acyl glycines as biosurfactants and therapeutics is highly desirable to replace chemical pathways using toxic phosgene. Herein, we report a novel concept for enzymatic amidation in an aqueous system via glycerol activation of fatty acids and theirsubsequent aminolysis with glycine to synthesize N-acyl glycines. We then engineer an enzyme (proRML) by reshaping its catalytic pocket to enhance its aminolysis activity and catalytic efficiency by 103-fold and 465-fold, respectively. The evolved proRML (D156S/L258K/L267N/S83D/L58K/R86K/W88V) catalyzed the amidation of a fatty acid with glycine to give N-lauroylglycine with high yield (80 %). It accepts a broad range of medium- to long-chain fatty acids (C₈ -C₁₈ ), giving high yields of N-decanoyl-, N-myristoyl-, and N-oleoylglycine. The developed amidation concept may be general, and the engineered enzyme is useful for the green synthesis of N-acyl glycines.

Effect of the acyl-group length on the chemoselectivity of the lipase-catalyzed acylation of propranolol-a computational study

The selective N-acylation of 1,2-amino alcohols has been proposed to occur through the proton shuttle mechanism. However, the O-acetylation of propranolol catalyzed by Candida antarctica lipase B is an exception. We investigated the relation between the chemoselectivity of this reaction and the acyl group length. For this purpose, we compared the acyl groups: ethanoyl, butanoyl, octanoyl, and hexadecanoyl. We studied the Michaelis complexes between serine-acylated Candida antarctica lipase B and propranolol, employing a computational approach that involved sampling Michaelis complex conformations through ensemble docking plus consensus scoring and molecular dynamics simulations. The conformations were then classified as near attack conformations for acylation of the amino or hydroxy group. The relative populations of these two classes of conformations were found to be consistent with the experimentally observed chemoselective O-acetylation. We predict that increasing the length of the hydrocarbon chain of the acyl group will cause O-acylation to be unfavorable with respect to N-acylation. The nucleophilic attack of propranolol to the acylated lipase was found to be more favorable through the classical mechanism when compared with the proton shuttle mechanism.

Direct synthesis of amides from nonactivated carboxylic acids using urea as nitrogen source and Mg(NO3)2 or imidazole as catalysts

A new method for the direct synthesis of primary and secondary amides from carboxylic acids is described using Mg(NO3)2·6H2O or imidazole as a low-cost and readily available catalyst, and urea as a stable, and easy to manipulate nitrogen source. This methodology is particularly useful for the direct synthesis of primary and methyl amides avoiding the use of ammonia and methylamine gas which can be tedious to manipulate. Furthermore, the transformation does not require the employment of coupling or activating agents which are commonly required.

Imido-substituted triazines as dehydrative condensing reagents for the chemoselective formation of amides in the presence of free hydroxy groups

In this paper, we discuss the synthesis of imido-substituted chlorotriazines and demonstrate their use in dehydrative condensation reactions. Chemoselective amide-forming reactions of amino alcohols using succinimido-substituted chlorotriazine (2A) proceeded smoothly. Occasionally, nonselectivity was problematic during the synthesis of hydroxy-substituted amides. Moreover, it was noteworthy that this method was applicable to hydroxy-substituted carboxylic acids that could have formed a lactone or an ester during the carboxylic acid activation step. The imido-substituted chlorotriazine (2A) was superior to the amido-substituted chlorotriazine and 2-chloro-4,6-dimethoxy-1,3,5-triazine (CDMT) in terms of reaction rates and yields.

In this paper, we discuss the synthesis of imido-substituted chlorotriazines and demonstrate their use in dehydrative condensation reactions.

Aminolysis of triglycerides using nanocrystalline nickel doped CaO as an efficient solid catalyst

A Ni/CaO catalyst is able to catalyze (A) aminolysis as well as (B) transesterification reactions.

Enzymatic strategies and biocatalysts for amide bond formation: tricks of the trade outside of the ribosome

Amide bond-containing (ABC) biomolecules are some of the most intriguing and functionally significant natural products with unmatched utility in medicine, agriculture and biotechnology. The enzymatic formation of an amide bond is therefore a particularly interesting platform for engineering the synthesis of structurally diverse natural and unnatural ABC molecules for applications in drug discovery and molecular design. As such, efforts to unravel the mechanisms involved in carboxylate activation and substrate selection has led to the characterization of a number of structurally and functionally distinct protein families involved in amide bond synthesis. Unlike ribosomal synthesis and thio-templated synthesis using nonribosomal peptide synthetases, which couple the hydrolysis of phosphoanhydride bond(s) of ATP and proceed via an acyl-adenylate intermediate, here we discuss two mechanistically alternative strategies: ATP-dependent enzymes that generate acylphosphate intermediates and ATP-independent transacylation strategies. Several examples highlighting the function and synthetic utility of these amide bond-forming strategies are provided.

An azobenzene-containing metal–organic framework as an efficient heterogeneous catalyst for direct amidation of benzoic acids: synthesis of bioactive compounds

An Zr-MOFs was demonstrated to be an efficient heterogeneous catalyst for direct amidation.

Immobilised lipases in the cosmetics industry

Commercial products for personal care, generally perceived as cosmetics, have an important impact on everyday life worldwide. Accordingly, the market for both consumer products and specialty chemicals comprising their ingredients is considerable. Lipases have started to play a minor role as active ingredients in so-called 'functional cosmetics' as well as a major role as catalysts for the industrial production of various specialty esters, aroma compounds and active agents. Interestingly, both applications almost always require preparation by appropriate immobilisation techniques. In addition, for catalytic use special reactor concepts often have to be employed due to the mostly limited stability of these preparations. Nevertheless, these processes show distinct advantages based on process simplification, product quality and environmental footprint and are therefore apt to more and more replace traditional chemical processes. Here, for the first time a review on the various aspects of using immobilised lipases in the cosmetics industry is given.

Catalytic amide formation from non-activated carboxylic acids and amines

The amide functionality is found in a wide variety of biological and synthetic structures such as proteins, polymers, pesticides and pharmaceuticals. Due to the fact that synthetic amides are still mainly produced by the aid of coupling reagents with poor atom-economy, the direct catalytic formation of amides from carboxylic acids and amines has become a field of emerging importance. A general, efficient and selective catalytic method for this transformation would meet well with the increasing demands for green chemistry procedures. This review covers catalytic and synthetically relevant methods for direct condensation of carboxylic acids and amines. A comprehensive overview of homogeneous and heterogeneous catalytic methods is presented, covering biocatalysts, Lewis acid catalysts based on boron and metals as well an assortment of other types of catalysts.

Preparation and Surface Activities of Novel Sodium Sulfated Aryl Oleic Acid Alkanolamides

Novel sodium sulfated aryl oleic acid alkanolamide surfactants (SSAOAA) with different hydrophobic groups are prepared. An aromatic ring introduced to a long alkyl chain has a significant effect on the effectiveness in reducing water surface tension. The critical micelle concentration (c.m.c.) of one product and the surface tension (γc.m.c.) at the c.m.c. are investigated. Surface active properties of sodium sulfated aryl oleic acid alkanolamides are compared to those of conventional sulfated fatty acid alkanolamides. Results show that the c.m.c. decreases with increasing the sizes of alkyl chains.

Monolayer characteristics of a long-chain N,O-diacyl substituted ethanolamine at the air/water interface

The N- and/or O-acylation of amphiphilic ethanolamine attracts particular attention because of its interesting biological, pharmaceutical, and medicinal properties. Tetradecanoic acid-2-[(1-oxotetradecyl)amino]ethyl ester (TAOAE) as the selected N,O-diacyl derivative of ethanolamine has been synthesized in order to obtain first information about its main interfacial characteristics, such as the surface pressure-area (π-A) isotherms, the morphology of the condensed phase domains, the lattice structure of the condensed phase, and information about the existence of interfacial hydrogen bonds (-NH···O═C-). The π-A isotherms of TAOAE, similar to those of the most usual monolayers of amphiphiles, show a sharp break point (A(c)) indicating the first-order phase transition from the fluid (liquid-expanded (LE), gaseous (G)) to the condensed (liquid-condensed (LC)) phase. On the mesoscopic scale, the dendritic domains homogeneously reflecting suggest an orientation of the alkyl chains perpendicular to the aqueous surface. The grazing incidence X-ray diffraction (GIXD) studies reveal hexagonal packing of the TAOAE molecules oriented perpendicular to the surface in an LS phase. The existence of a hydrogen-bonding network in the monolayer is supported by infrared reflection absorption spectroscopy (IRRAS) experiments.

Enzymatic chemoselective synthesis of secondary-amide surfactant from N-methylethanol amine

Efficient selective synthesis of the secondary amide surfactant N-methyl lauroylethanolamide from methyl laurate and N-methylethanol amine by carrier-fixed Chirazyme L-2 (Candida antarctica) using a kinetic strategy has been demonstrated. When different solvents were screened for product yields using Chirazyme L-2, acetonitrile was found to be optimal. The rate of the reaction increased sharply by increasing the molar ratio of the reactants and the reaction temperature. When the reaction was performed at 50 degrees C for 36 h with 50 mmol ester and 100 mmol amine, the product was obtained in a 97.1% yield. With 50 mmol ester and 150 mmol amine, the highest yield (97.3%) was obtained after 16 h of incubation at 50 degrees C. It took only 5 h to get a yield of 95.8% at 60 degrees C using 50 mmol ester and 200 mmol amine. The enzyme activity in the amidation reaction mixture did not decrease notably even after six uses.

Enzymatic synthesis of amide surfactants from ethanolamine

The condensation of a primary amine with fatty acids has been studied to determine optimum conditions for selective formation of amide surfactants via enzymatic amidification. Monoacylated ethanolamide and the diacylated amide-ester can be isolated from the reaction mixture, but the monoacylated ester cannot be isolated. The selectivity of the reaction depends on the solubility of the intermediate amide. Continuous precipitation of this product decreases the amount of amide-ester produced. Solubility values of the desired product (amide) are reported for different conditions.In acetonitrile, the ethyl ester of the corresponding fatty acid has been used successfully to avoid formation/precipitation of the ion-pair of the precursor reagents. In this medium, use of the transacylation reaction permits one to accelerate the reaction without producing a significant change in the selectivity toward the intermediate amide. This strategy is not successful in n-hexane where the solubilities of both ethanolamine and its ion-pair with lauric acid are similar.Results obtained for high loadings of substrates have been analyzed. In n-hexane and acetonitrile, the kinetics of the direct acylation reactions are controlled by the limited solubility of the ion pair formed by the two precursor reagents For the transacylation reaction in acetonitrile, at a sustrate loading of 2 mol l(-1,) selective production of as much as 92 mole percent N-acyl ethanolamine was observed in only 1.5 h.

Chemoenzymatic synthesis of surfactants from carbohydrates, amino acids, and fatty acids

The chemoenzymatic synthesis of new surfactants is reported; they were prepared from unprotected carbohydrates, amino acids, and fatty acids. This study pointed out the factors that govern the possibility to enzymatically bind the carbohydrate to the amino acid.

Lipase and esterase-catalyzed acylation of hetero-substituted nitrogen nucleophiles in water and organic solvents

The lipase- and esterase-catalyzed acylations of hydroxylamine and hydrazine derivatives with octanoic acid and ethyl octanoate are described. The influence of solvent and nucleophile on the initial reaction rate was investigated for a number of free and immobilized enzymes. Initial rates were highest in water, but the overall productivity was optimal in dioxane. Octanoic acid (250 g/L) was converted for 93% into the hydroxamic acid in 36 h with only 1% (w/w) Candida antarctica lipase B (Novozym 435) in dioxane at 40 degrees C. This translates to a catalyst productivity of 68.5 g. g(-1). day(-1) and a space time yield of 149 g. L(-1). day(-1), unprecedented figures in the direct reaction of an acid with a nitrogen nucleophile in an organic solvent.

Biocatalysis in nonaqueous solvents

Biotransformation technologies have enjoyed a renewed interest from researchers and industry because of the progress made in the discovery and design of new, efficient biocatalysts for synthetic applications. Biocatalysis in nonaqueous media, which offers unique capabilities and thus plays a major role in biotransformation technologies, has made tremendous progress in recent years. On average, at least one paper dealing with biocatalysis in organic solvents is published every day. New, remarkable developments have taken place in several key areas of this exciting field during the past year.

Kinetic study of chemoselective acylation of amino-alditol by immobilized lipase in organic solvent: effect of substrate ionization

The kinetics of the lipase-catalyzed synthesis of oleoyl-N-methylglucamide and 6-O-oleoyl-N-methylglucamine in organic systems were investigated. We have shown that in apolar media, the ionic state of substrates and the ionic state of enzyme microenvironment play an important role in immobilized Candida antarctica lipase activity and chemoselectivity of the reaction. In order to define the optimal conditions of the reaction, to obtain the highest initial rate for amide formation, the influence of acid/N-methylglucamine molar ratio is studied. This ratio determines the protonation states of substrates and of ionizable groups of catalytic site, on which the enzyme activity is dependent. To confirm our hypothesis, we have added to the medium a non-reactive base which is not a substrate of the enzyme. We observed that when the acid/base ratio is higher than 1, the initial rate of ester synthesis increases whereas that of amide synthesis decreases. On the opposite, when the acid/base ratio is lower than 1, the initial rate of amide synthesis becomes preponderant.