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Fatty acids poly ester

A variety of waxy hydrophobic hydrocarbon-based soHd phases are used including fatty acid amides and sulfonamides, hydrocarbon waxes such as montan wax [8002-53-7], and soHd fatty acids and esters. The amides are particularly important commercially. One example is the use of ethylenediamine distearamide [110-30-5] as a component of latex paint and paper pulp blackHquor defoamer (11). Hydrocarbon-based polymers are also used as the soHd components of antifoaming compositions (5) examples include polyethylene [9002-88-4], poly(vinyl chloride) [9002-86-2], and polymeric ion-exchange resins. [Pg.463]

Ester synthesis of fatty acid ethyl ester. The lipase-catalyzed esterification of fatty acid and alcohol is well-known. It was also favorable for the esterification of poly unsaturated fatty acids under mild conditions with the enzyme. However, the activity of native lipase is lower in polar organic solvents, i.e. ethanol and methanol. The synthesis of Ae fatty acid ethyl ester was carried out in ethanol using the palmitic acid-modified lipase. As shown in Figure 7, the reactivity of the modified lipase in this system was much higher than that of the unmoditied lipase. [Pg.179]

Fatty acid polygiycol ester Fatty acids source oil xoconut Fatty acids source oihsoya Fatty acids source oil mixed Fatty alcohol/ethylene oxide condensate Fatty alcohol sulfates Fatty amide Fatty amide Fatty amide blend Fatty amides and cationic poly-ethylenes blend Fatty amide condensate Fatty amide condensate wax Fatty amidoquaternary Fatty amine Fatty amine... [Pg.660]

This paper presents data on isolation and identification of the following types of geolipids from the Aleksinac oil shale, a Miocene lake sediment n-al-kanes, iso- and/or anteiso-alkanes, aliphatic iso-prenoid alkanes, polycyclic isoprenoid alkanes, aromatic hydrocarbons, saturated unbranched, aliphatic isoprenoid, hopanoic, and aromatic mono- and poly-carboxylic acids, fatty acid methyl esters, aliphatic y- and 6-lactones, cyclic y-lactones, aliphatic methyl- and isoprenoid ketones, and the triterpenoid ketone adiantone. Possible origin of the identified compound classes is discussed, particularly of those which had not been identified previously as geolipids. [Pg.43]

P liquid bonded Poly(alkylene glycol) 240 Fatty acid methyl esters, phenols, fragrance oils, and aldehydes/ketones... [Pg.484]

Other food emulsifiers are made by transesterification of fatty acid methyl esters with poly glycerols, sorbitan, sucrose and stearoyl lactate (Figure 10.2). Sugar, sorbitan fatty esters and polyoxyethylene sorbitan esters are used to stabilize oil-in-water food emulsions. Optimum emulsification is achieved with combinations of emulsifiers. Margarines are made with a combination of monoglycerides and lecithin, and cake mixes with a mixture of monoglycerides and propylene glycol monoesters. [Pg.265]

Relative amounts of monomers in purified PHA (%, wt/wt), determined by GC and GC-MS of the respective 3-hydroxy fatty acid methyl esters after hydrolysis of the poly(HAMCL)s-Trace amounts (<0.1%, wt/wt). [Pg.266]

The Shell higher olefin process (SHOP process) is an example for ethenolysis on an industrial scale. From the ethenolysis of an oleic double bond such as in tall oil fatty acid methyl ester using a Grubbs catalyst methyl-9-decenoate and 1-decene are formed (Figure 3B.15) key intermediates in the synthesis of flavors and fragrances, insect pheromones as environmentally friendly alternatives to pesticides, and prostaglandins on the one side and poly-a-olefins as lubricant base stock on the other. ... [Pg.141]

Figure 10. Isolhernial analysis (200 °C) of fatty acid methyl esters on a capillary column with high-W, poly(ethylene glycol) as... Figure 10. Isolhernial analysis (200 °C) of fatty acid methyl esters on a capillary column with high-W, poly(ethylene glycol) as...
The nonionic emulsifiers are rarely used in the emulsion polymerization. This group includes esters of glycerol and fatty acids, products of ethylene oxide addition to alcohols, phenols or fatty acids, poly (vinyl alcohol) and others. [Pg.336]

A graft copolymer was prepared by Rohm GmbH [16] by copol5nnerizing 10-90 wt% of a poly(aIkyl methacrylate) macromonomer with Ce 30 alkyl methacrylates, Ci s alkyl methacrylates, styrene, Ci 4 alkyl styrene, <60 wt% C2-12 fatty acid vinyl esters, and <40 wt% functionalized comonomers from a group of vinyl heterocycles and fimctionalized methacrylates and amides. The lubricant additive was reported to have pronounced Vl-improving and dispersing efficiency. [Pg.436]

N-Benzylamides are recommended when the corresponding acid is liquid and/or water-soluble so that it cannot itself serve as a derivative. Phe benzylamides derived from the simple fatty acids or their esters are not altogether satisfactory (see Table below) those derived from most hydroxy-acids and from poly basic acids or their esters are formed in good yield and are easily purified. The esters of aromatic acids yield satisfactory derivatives but the method must compete with the equally simple process of hydrolysis and precipitation of the free acid, an obvious derivative when the acid is a solid. The procedure fails with esters of keto, sul phonic, inorganic and some halogenated aliphatic esters. [Pg.394]

Lignites and lignosulfonates can act as o/w emulsifiers, but generally are added for other purposes. Various anionic surfactants, including alkylarylsulfonates and alkylaryl sulfates and poly(ethylene oxide) derivatives of fatty acids, esters, and others, are used. Very Httle oil is added to water-base muds in use offshore for environmental reasons. A nonionic poly(ethylene oxide) derivative of nonylphenol [9016-45-9] is used in calcium-treated muds (126). [Pg.182]

A major pharmaceutical use of poly(oxyethylene) sorbitan fatty acid esters is in the solubilization of the oil-soluble vitamins A and D. In this way, multivitamin preparations can be made which combine both water- and oil-soluble vitamins in a palatable form. [Pg.54]

Emulsions of fatty- and petroleum-based substances, both oils and waxes, of the o/w type are made by using blends of sorbitan fatty esters and their poly(oxyethylene) derivatives. Mixtures of poly(oxyethylene(20)) sorbitan monostearate (Polysorbate 60) and sorbitan monostearate are typical examples of blends used for lotions and creams. Both sorbitan fatty acid esters and their poly(oxyethylene) derivatives are particularly advantageous in cosmetic uses because of their very low skin irritant properties. Sorbitan fatty ester emulsifiers for w/o emulsions of mineral oil are used in hair preparations of both the lotion and cream type. Poly(oxyethylene(20)) sorbitan monolaurate is useflil in shampoo formulations (see Hairpreparations). Poly(oxyethylene) sorbitan surfactants are also used for solubilization of essential oils in the preparation of colognes and after-shave lotions. [Pg.54]

Many similar hydrocarbon duids such as kerosene and other paraffinic and naphthenic mineral oils and vegetable oils such as linseed oil [8001-26-17, com oil, soybean oil [8001-22-7] peanut oil, tall oil [8000-26-4] and castor oil are used as defoamers. Liquid fatty alcohols, acids and esters from other sources and poly(alkylene oxide) derivatives of oils such as ethoxylated rosin oil [68140-17-0] are also used. Organic phosphates (6), such as tributyl phosphate, are valuable defoamers and have particular utiHty in latex paint appHcations. Another important class of hydrocarbon-based defoamer is the acetylenic glycols (7), such as 2,4,7,9-tetramethyl-5-decyne-4,7-diol which are widely used in water-based coatings, agricultural chemicals, and other areas where excellent wetting is needed. [Pg.463]

Transesterification has a number of important commercial uses. Methyl esters of fatty acids are produced from fats and oils. Transesterification is also the basis of recycling technology to break up poly(ethylene terephthalate) [25038-59-9] to monomer for reuse (29) (see Recycling, plastics). Because vinyl alcohol does not exist, poly(vinyl alcohol) [9002-89-5] is produced commercially by base-cataly2ed alcoholysis of poly(vinyl acetate) [9003-20-7] (see Vinyl polymers). An industrial example of acidolysis is the reaction of poly(vinyl acetate) with butyric acid to form poly(vinyl butyrate) [24991-31-9]. [Pg.388]

Surface-Active Agents. Polyol (eg, glycerol, sorbitol, sucrose, and propylene glycol) or poly(ethylene oxide) esters of long-chain fatty acids are nonionic surfactants (qv) used in foods, pharmaceuticals, cosmetics, textiles, cleaning compounds, and many other appHcations (103,104). Those that are most widely used are included in Table 3. [Pg.396]

Finally, ion chromatography can be used to determine the a-sulfo fatty acid esters. The chromatographic column is a nonpolar poly sty rene/divinylbenzene column and the ion pair reagent is 0.005 M ammonia. In order to reduce the elution time, acetonitrile is added as a modifier with increasing concentration. This gradient technique makes it possible to separate simultaneously ester sulfonates and disalts by chain length. Determination is achieved by standards with defined chain length [107]. [Pg.493]

The poly(3HO) depolymerase differs from poly(HASCL) depolymerases in several of its biochemical properties it is specific for poly(HAMCL) and for artificial esters such as p-nitrophenylacyl esters with six or more carbon atoms in the fatty acid moiety. Poly(3HB) and other poly(HASCL) are not hydrolyzed. The enzyme is not inhibited by dithioerythritol or by EDTA and therefore apparently does not contain essential disulfide bonds. It is also not dependent on Ca2+ or other divalent cations. [Pg.306]

The i-poly(3HB) depolymerase of R. rubrum is the only i-poly(3HB) depolymerase that has been purified [174]. The enzyme consists of one polypeptide of 30-32 kDa and has a pH and temperature optimum of pH 9 and 55 °C, respectively. A specific activity of 4 mmol released 3-hydroxybutyrate/min x mg protein was determined (at 45 °C). The purified enzyme was inactive with denatured poly(3HB) and had no lipase-, protease-, or esterase activity with p-nitro-phenyl fatty acid esters (2-8 carbon atoms). Native poly(3HO) granules were not hydrolyzed by i-poly(3HB) depolymerase, indicating a high substrate specificity similar to extracellular poly(3HB) depolymerases. Recently, the DNA sequence of the i-poly(3HB) depolymerase of R. eutropha was published (AB07612). Surprisingly, the DNA-deduced amino acid sequence (47.3 kDa) did not contain a lipase box fingerprint. A more detailed investigation of the structure and function of bacterial i-poly(HA) depolymerases will be necessary in future. [Pg.316]

Another class of PSA-fatty acid-based copolymers has been synthesized from the ricinoleic acid and ricinoleic half-esters with maleic and succinic anhydride, poly(sebacic-co-ricinoleic acid maleate), poly(sebacic-co-ricinoleic acid succinate), and poly(sebacic-co-12-hydroxystearic acid succinate) (P(SA-RAM), P(SA-RAS), and P(SA-HSAS)) (Krasko et al., 2003 Teomim et al., 1999). These syntheses result in poly(anhydride-co-esters). [Pg.179]

Akiyama, Y., Nagahara, N., Kashihara, T., Hirai, S., and Toguchi, H., In vitro and in vivo evaluation of mucoadhesive microspheres prepared for the gastrointestinal tract using polyglycerol esters of fatty acids and a poly(acrylic acid) derivative, Pharm. Res., 12 397-405... [Pg.191]

Louis-Jacques Thenard, 1777-1857. Professor of chemistry at the Ecole Poly-technique. Discoverer of hydrogen peroxide. Collaborator with Gay-Lussac m his researches on potassium, boron, lodme, and chlorine. He also investigated many fatty acids, esters and ethers... [Pg.574]


See other pages where Fatty acids poly ester is mentioned: [Pg.62]    [Pg.263]    [Pg.377]    [Pg.377]    [Pg.217]    [Pg.1896]    [Pg.208]    [Pg.253]    [Pg.438]    [Pg.351]    [Pg.668]    [Pg.701]    [Pg.151]    [Pg.363]    [Pg.53]    [Pg.54]    [Pg.55]    [Pg.373]    [Pg.25]    [Pg.385]    [Pg.217]    [Pg.903]    [Pg.267]    [Pg.268]   
See also in sourсe #XX -- [ Pg.67 ]

See also in sourсe #XX -- [ Pg.67 ]




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