ascorbic-acid and lauric-acid

6-O-Dodecanoyl-2-O-α-D-glucopyranosyl-L-ascorbic acid (6-sDode-AA-2G) was synthesized from 2-O-α-D-glucopyranosyl-L-ascorbic acid and lauric anhydride with a polymer catalyst, poly(4-vinylpyridine), in N,N-dimethylformamide without the introduction of protecting groups. The optimum reaction conditions enabled 6-sDode-AA-2G to be synthesized in a yield of 49.7%. The yield and the regioselectivity in this method were far superior to those in our previous method by using an enzyme. The polymer catalyst could be recycled more than five times without any significant activity loss.

Topics: Acylation; Anhydrides; Ascorbic Acid; Catalysis; Chemistry Techniques, Synthetic; Dimethylformamide; Formamides; Glucosides; Kinetics; Lauric Acids; Polyvinyls; Solvents; Stereoisomerism

The objective in this work is to determine the antioxidant capacity and effectiveness of icariin (2-(4'-methoxylphenyl)-3-rhamnosido-5-hydroxyl-7-glucosido-8-(3'-methyl-2-butylenyl)-4-chromanone), the major component in herba epimedii being used widely in traditional Chinese medicine for the treatment of artherosclerosis and neuropathy, in which 2,2'-azobis(2-amidinopropane) dihydrochloride (AAPH)-induced peroxidation of linoleic acid (LH) in sodium dodecyl sulfate (SDS) acts as the experimental system. By containing an intramolecular hydrogen bond, icariin protects LH against AAPH-induced peroxidation of LH only in SDS, an anionic micelle. The number of trapping peroxyl radicals (LOO(*)), n, by icariin is just 0.0167 whereas alpha-tocopherol (TOH) and L-ascorbyl-6-laurate (VC-12) are 2.14 and 1.25, respectively, with reference to the n of 6-hydroxyl-2,5,7,8-tetramethylchroman-2-carboxylic acid (Trolox), 2.00. This is also related to how the intramolecular hydrogen bond enhances the bond dissociation enthalpy (BDE) of O-H in icariin. However, calculation of the inhibition rate constant, k(inh), a kinetic parameter to describe the reaction between the antioxidant and LOO(*), results in a k(inh) of icariin at about one magnitude larger than those of Trolox, TOH, and VC-12. This fact reveals that, by the view of kinetics, icariin is an antioxidant with much higher effectiveness. In addition, the antioxidant capacities of icariin used together with other antioxidants have been determined and the results indicate that the n of icariin decreases markedly while the n values of Trolox and TOH increase, even if the n of icariin is a negative value in the presence of VC-12. Furthermore, an analysis of k(inh) in this case reveals that the k(inh)(icariin) increases nearly one magnitude with the decrease of k(inh)(Trolox) and no remarkable change occurs for k(inh)(TOH). The negative value of k(inh)(icariin) in the presence of VC-12 can be regarded as the icariin functions as a prooxidant that can be rectified by VC-12 effectively. These findings implicate that the evaluation of antioxidant activity should not only focus on an n value, a thermodynamic possibility, but k(inh) and the charge property of the micelle should be also taken into account. To some extent, the latter factors are more important than the thermodynamic possibility.

Topics: Algorithms; Antioxidants; Ascorbic Acid; Chromans; Flavonoids; Free Radicals; Hydrogen Bonding; Kinetics; Lauric Acids; Linoleic Acid; Lipid Peroxidation; Micelles; Sodium Dodecyl Sulfate

6-O-Palmitoyl L-ascorbate was added to linoleic acid at various molar ratios of the ascorbate to the acid, the mixtures were emulsified with a maltodextrin or gum arabic solution, and the emulsions were spray-dried to produce microcapsules. At higher molar ratios, the oil droplets in the emulsions were smaller, and the oxidative stabilities of the encapsulated linoleic acid were higher for both the maltodextrin- and gum arabic-based microcapsules. 6-O-Capryloyl, caproyl, and lauroyl L-ascorbates, which were synthesized through lipase-catalyzed condensation in acetone, were also used for the microencapsulation of linoleic acid. Except for capryloyl L-ascorbate, the addition of a saturated acyl ascorbate, especially caproyl ascorbate, to linoleic acid was effective for preparing oil droplets of small particle diameter and for suppressing the oxidation of the encapsulated linoleic acid.

Topics: Acylation; Antioxidants; Ascorbic Acid; Caprylates; Capsules; Decanoic Acids; Drug Stability; Emulsions; Gum Arabic; Lauric Acids; Linoleic Acid; Oxidation-Reduction; Polysaccharides; Solubility; Time Factors

The oil/water distribution coefficients of ascorbic acid and dehydro-L-ascorbic acid have been determined and compared with values for mannitol and lauric acid. In general, the relative degrees of hydrophobicity of the compounds evaluated are lauric acid much greater than mannitol approximately equal to dehydro-L-ascorbic acid greater than ascorbic acid. These findings and recent reports from transport studies do not support the concept that dehydro-L-ascorbic acid is very hydrophobic and crosses cell membranes rapidly by simple diffusion.

Topics: Ascorbic Acid; Cell Membrane Permeability; Dehydroascorbic Acid; Lauric Acids; Mannitol; Models, Biological; Oils; Oxidation-Reduction; Permeability; Water