Amine acrylate synthesis

Amine Acrylate Synthesis. During this study a number of amine acrylates and model compounds were synthesised. The syntheses were based on the Michael type addition of a secondary amine to an activated acrylate double bond. Our procedure is as follows. 

In a further example of indium-mediated additions to aldoses, a-(bromo-methyl)acrylic acid added to A-acetylmannosamine in the presence of indium to give branched derivative 27 and its C-4 epimer. Ozonolysis of 27 afforded N-acetylneuraminic acid. In a study of the oxidation of L-sorbose (5% Pt/AlaOa, O2) to 2-keto-L-gulonic acid it was found that the reaction rate and selectivity was improved in the presence of certain tertiary amines. The synthesis of a carbocyclic analogue of iV-acetyl-neuraminic acid is discussed in Chapter 18. 

Catalysts. Silver and silver compounds are widely used in research and industry as catalysts for oxidation, reduction, and polymerization reactions. Silver nitrate has been reported as a catalyst for the preparation of propylene oxide (qv) from propylene (qv) (58), and silver acetate has been reported as being a suitable catalyst for the production of ethylene oxide (qv) from ethylene (qv) (59). The solubiUty of silver perchlorate in organic solvents makes it a possible catalyst for polymerization reactions, such as the production of butyl acrylate polymers in dimethylformamide (60) or the polymerization of methacrylamide (61). Similarly, the solubiUty of silver tetrafiuoroborate in organic solvents has enhanced its use in the synthesis of 3-pyrrolines by the cyclization of aHenic amines (62). 

The formation of an enamine from an a,a-disubstituted cyclopentanone and its reaction with methyl acrylate was used in a synthesis of clovene (JOS). In a synthetic route to aspidospermine, a cyclic enamine reacted with methyl acrylate to form an imonium salt, which regenerated a new cyclic enamine and allowed a subsequent internal enamine acylation reaction (309,310). The required cyclic enamine could not be obtained in this instance by base isomerization of the allylic amine precursor, but was obtained by mercuric acetate oxidation of its reduction product. Condensation of a dihydronaphthalene carboxylic ester with an enamine has also been reported (311). 

Uses of Methylamines. Dimethylamine is the most widely used of the three amines. Excess methanol and recycling monomethylamine increases the yield of dimethylamine. The main use of dimethylamine is the synthesis of dimethylformamide and dimethylacetamide, which are solvents for acrylic and polyurethane fibers. 

The preparation of fluorinated alcohols was carried out in multistep routes according to the reported procedures.1012 The synthesis of acrylic and methacrylic esters as shown in Table 11.1 was carried out in a fluorocarbon solvent such as Freon 113 by the reaction of the respective fluorinated alcohol with acryloyl chloride or methacryloyl chloride and an amine acid acceptor such as triethyla-mine with examples shown in Scheme 1. Other attempts to esterify the fluoroalcohols directly with acrylic acid or acrylic anhydride were not successful.11 Product purification by distillation was not feasible because of the temperature required, but purification by percolation of fluorocarbon solutions through neutral alumina resulted in products of good purity identified by TLC, FTIR, and H-, 13C-, and 19F- FTNMRs. 

The complete transformation of a racemic mixture into a single enantiomer is one of the challenging goals in asymmetric synthesis. We have developed metal-enzyme combinations for the dynamic kinetic resolution (DKR) of racemic primary amines. This procedure employs a heterogeneous palladium catalyst, Pd/A10(0H), as the racemization catalyst, Candida antarctica lipase B immobilized on acrylic resin (CAL-B) as the resolution catalyst and ethyl acetate or methoxymethylacetate as the acyl donor. Benzylic and aliphatic primary amines and one amino acid amide have been efficiently resolved with good yields (85—99 %) and high optical purities (97—99 %). The racemization catalyst was recyclable and could be reused for the DKR without activity loss at least 10 times. 

Uses Solvent in nitrocellulose coatings, vinyl films and Glyptal resins paint removers cements and adhesives organic synthesis manufacture of smokeless powders and colorless synthetic resins preparation of 2-butanol, butane, and amines cleaning fluids printing catalyst carrier acrylic coatings. 

Another approach for the synthesis of networks relies on the polycondensation of multifunctionalized polyesters with the appropriate multifunctionalized agent, provided that one of the partner is at least tri-functionalized. Toward this end, several reaction have been reported, such as the Michael addition of amines onto acrylates [184], the coupling of ketones and oxyamines [185], the click copper(II)-catalyzed azide-alkyne cycloaddition [186], and esterification reactions [25, 159, 187]. Interestingly, if esterification reactions are used, the crosslinks are then degradable. 

The divergent method is illustrated in Fig. 2-22 for the synthesis of polyamidoamine (PAMAM) dendrimers [Tomalia et al., 1990]. A repetitive sequence of two reactions are used—the Michael addition of an amine to an a,P-unsaturated ester followed by nucleophilic substitution of ester by amine. Ammonia is the starting core molecule. The first step involves reaction of ammonia with excess methyl acrylate (MA) to form LXIII followed by reaction with excess ethylenediamine (EDA) to yield LXIV. LXV is a schematic representation of the dendrimer formed after four more repetitive sequences of MA and EDA. 

The synthesis of the moxifloxacin core (de Souza, 2006 Martel et al., 1997 Seidel et al., 2000) proceeds from a Grohe-Heitzer sequence as described earlier in the chapter. Unlike the traditional Grohe-Heitzer sequence, however, the opening step involved the reaction between acid chloride 101 with the mono potassium salt of malonic acid monoethyl ester (102) in the presence of triethylamine to deliver ketoester 103 (Scheme 4.18). Treatment of 103 with ethyl orthoformate furnished acrylate 104, which reacted with cyclopropyl amine to afford 105. Cyclization of 105 in the presence of sodium fluoride in DMF gave the moxifloxicin core 106. 

A very popular route to piperid-4-ones is by a Dieckmann or Thorpe cyclization of appropriate diesters or dinitriles. In most cases the nitrogen atom is tertiary, to avoid the formation of amides as by-products. A simple example is provided by the synthesis of the piperidone ester (129) which, after hydrolysis and decarboxylation, gives the piperid-4-one (130) (45JOC277). The diesters are available by addition of amines to acrylates and so the two ester fragments can be different. For the production of AT-benzoylpiperid-4-one (132) the whole operation from benzamide and ethyl acrylate to the ester (131) can be achieved... 

Intramolecular aminopalladation has been applied to the total synthesis of the complex skeleton of bukittinggine (179). For this reaction. Pd(CF3CO )2 (10 mol%) and benzoquinone (1.1 equiv.) are used. It is important to use freshly recrystallized benzoquinone for successful cyclization. Formation of a 7r-allylpalladium species as an intermediate in this amination reaction has been suggested 182]. The amino group in obromoaniline reacts first with acrylate in the presence of PdCF to give 180, and then intramolecular Heck reaction of the resulting alkene 180 with Pd(0) catalyst affords indolecarboxylate 181[183]. 

The hrst step in the preparation of the antidepressant maprotiline (33-5) takes advantage of the acidity of anthrone protons for incorporation of the side chain. Thus treatment of (30-1) with ethyl acrylate and a relatively mild base leads to the Michael adduct saponihcation of the ester group gives the corresponding acid (33-1). The ketone group is then reduced by means of zinc and ammonium hydroxide. Dehydration of the hrst-formed alcohol under acidic conditions leads to the formation of fully aromatic anthracene (33-2). Diels-Alder addition of ethylene under high pressure leads to the addition across the 9,10 positions and the formation of the central 2,2,2-bicyclooctyl moiety (33-3). The hnal steps involve the construction of the typical antidepressant side chain. The acid in (33-3) is thus converted to an acid chloride and that function reacted with methylamine to form the amide (33-4). Reduction to a secondary amine completes the synthesis of (33-5) [33]. 

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