Methyl ester amide

DithiomethoxymethyIphenol, 306 Di-p-toluoyl-o-tartrate, 351 Di-p-tolylcarbodiimide, 351-352, 1148 1,1-Di-p-tolylethane, 11, 659 Di-p-tolylthiourea, 351 N,0-Ditosyl-3-aminopropanol, 918 v/c-Ditosylates, 1089 Divinylmercury, 352-353 Docosanedioic add, 438, 708 -Dodecadiene, 1009 Dodecahydrotriphenylene, 991 Dodecane-l,2-dioic acid, 477,788 methyl ester amide, 212 Dodecanol, 958 Dodecanyl tosylate, 958-959... 

Alkyl chlorides Methyl ketones Methyl esters Amides... 

Table 5.1 Main IR bands and corresponding functional groups of methyl ester, amide of fatty acids and poly (ester amide)...

The aldol adducts (4) are easily converted to the corresponding -hydroxy-a-methyl esters, amides, and aldehydes. Treatment of (4) (R = Ph) with methanol or ethanol in the presence of potassium carbonate at room temperature gives the methyl or ethyl ester in high yield (eq 2) Similarly, the amide is spontaneously formed by mixing (4) with the amine in dichloromethane (eq 3). The preparation of the aldehyde is carried out by using diisobutyla-luminum hydride as a reductant after protection of the hydroxy function of (4) with the dimethylisopropylsilyl group (eq 4). No isomerization occurs during these conversions. 

In his cephalosporin synthesis methyl levulinate was condensed with cysteine in acidic medium to give a bicyclic thiazolidine. One may rationalize the regioselective formation of this bicycle with the assumption that in the acidic reaction mixture the tMoI group is the only nucleophile present, which can add to the ketone. Intramolecular amide formation from the methyl ester and acid-catalyzed dehydration would then lead to the thiazolidine and y-lactam rings. The stereochemistry at the carboxylic acid a-... 

Selected physical properties of various methacrylate esters, amides, and derivatives are given in Tables 1—4. Tables 3 and 4 describe more commercially available methacrylic acid derivatives. A2eotrope data for MMA are shown in Table 5 (8). The solubiUty of MMA in water at 25°C is 1.5%. Water solubiUty of longer alkyl methacrylates ranges from slight to insoluble. Some functionalized esters such as 2-dimethylaniinoethyl methacrylate are miscible and/or hydrolyze. The solubiUty of 2-hydroxypropyl methacrylate in water at 25°C is 13%. Vapor—Hquid equiUbrium (VLE) data have been pubHshed on methanol, methyl methacrylate, and methacrylic acid pairs (9), as have solubiUty data for this ternary system (10). VLE data are also available for methyl methacrylate, methacrylic acid, methyl a-hydroxyisobutyrate, methanol, and water, which are the critical components obtained in the commercially important acetone cyanohydrin route to methyl methacrylate (11). 

On heating, an alkanolamine soap first dehydrates to the amide this is also obtained from the methyl ester of the fatty acid by heating with the alkanolamine at 60°C in the presence of a catalytic amount of sodium methoxide. Methanol is removed under partial vacuum. At higher temperature, the amide is dehydrated to an oxa2oline. 

Amides can be produced from fatty acid methyl esters by reaction with ammonia at 220 °C at 12.4 MPa (1800 psi) pressure. Reaction times are reduced to 1 h by this route however, the fatty acid feedstocks must fkst be converted to methyl esters (21). 

Refluxing linoleic acid and a primary or secondary alkyl amine with -toluenesulfonic acid in toluene for 8—18 h also yields the substituted amides (32—34). The reaction of methyl esters with primary or secondary amines to make substituted amides is catalyzed with sodium methoxide. Reactions are rapid at 30°C under anhydrous conditions (35). Acid chlorides can also be used. Ai,A/-dibutyloleamide [5831-80-17 has been prepared from oleoyl chloride and dibutyl amine (36). 

A/- -toluene su1fony1)-T-phenylalanine (62), L-histidine methyl ester (63), A/-acetyl L-valine /-butyl amide (64), etc, are used as chiral addends. 

Alternatively, the acid (5g) is refluxed for 2h with 15mL of MeOH and 2mL of 98% H2SO4 (cool when mixing this soln). Pour into 10 volumes of H2O and extract with the minimum volume of CHCI3 to give clear separation of phases. The extract is washed with H2O and dried (CaCl2) and distd. The methyl ester is collected at 77-79°/ mm, m 38-39°. The ester is hydrolysed with the calculated amount of N KOH and refluxed until clear. Acidification with HCl provides the pure acid with 90% recovery. [Org Synth 4 1 1964.] The amide crysts from cyclohexane, m 189°. [Chem Ber 62 1629 1959.]... 

Ferrocene carboxylic acid [1271-42-7] M 230.1, m 210°(dec), 225-230°(dec). Yellow crystals from pet ether. Also crystd from aqueous ethanol. [Matsue et al. J Am Chem Soc 107 3411 1985.] Acid chloride m 49° crystallises from pentane, Xmax 458nm [J Org Chem 24 280 1959], Methyl ester crystallises from aq MeOH m 70-71°. Anhydride m 143-145° from pet ether [J Org Chem 24 1487 7959]. Amide m 168-170° from CHCl3-Et20 or m 167-169° from C6H6-MeOH. [J Am Chem Soc 77 6295 1955 76 4025 7954.]... 

For primary amides DMF dimethyl acetal, MeOH, 92-100% yield. The methyl ester is formed, but if MeOH is replaced with another alcohol, other esters can be prepared with similar efficiency. 

Addition of the alcohol 42 to a solution of BF3 Et20/TMSCN in DCM provided the nitrile 43 in 83% yield. Hydrolysis of nitrile 43 then furnished amide 44 in 85% yield. Demethylation of the methoxyindole 44 with BBra in DCM provided the hydroxyindole 45 in 80% yield. This was followed by alkylation of 45 with the bromide 46 under phase transfer conditions to provide the phosphonate ester 47 and subsequent cleavage of the methyl ester by TMS-I furnished trimethylsilyl phosphonic acid 48, which upon alcoholic workup afforded LY311727. 

With 1-hydroxytryptophan derivatives, similar substituent effects are observed (99H2815). In order to realize better yields of 5-substituted tryptophans, car-boxy and amino groups are transformed to ester and/or amide groups, choosing the 1-methoxy moiety as a leaving group. As a result, ( )-Ab-acetyl-5-chlorotryptophan methyl ester (219, 52%) is obtained together with 220 (7%) from ( )-218 by the reaction with aqueous HCl (Scheme 32). ( )-5-Bromo-Ab-methoxycarbonyltryptophan methylamide (222, 50%) becomes readily available... 

The chloro atom of 2-[4-(6-chloronicotinoyl)benzyloxy]-3-methyl-4//-pyrido[l,2-n]pyrimidin-4-one, its 6-methyl derivative and 2-[4-(6-chlo-ronicotinoyl)benzylthio]-3-methyl-4//-pyrido[l,2-n]pyrimidin-4-one was replaced by a 4-piperidinopiperidino and 4-phenylpiperazino group with 4-piperidinopiperidine and 4-phenylpiperazine (96EUP733633). The carboxyl group of 2-[4-(4-carboxybenzoyl)benzyloxy]-3-methyl-4//-pyrido[l,2-n]pyrimidin-4-one, prepared by hydrolysis of methyl ester in DMF with 1 N NaOH, was reacted first with diethyl pyrocarbonate in DMF at room temperature and then with 4-phenylpiperazine and 4-piperidinopiperidine to give the appropriate amide derivatives (96EUP733633). 

The complex thioamide lolrestat (8) is an inhibitor of aldose reductase. This enzyme catalyzes the reduction of glucose to sorbitol. The enzyme is not very active, but in diabetic individuals where blood glucose levels can. spike to quite high levels in tissues where insulin is not required for glucose uptake (nerve, kidney, retina and lens) sorbitol is formed by the action of aldose reductase and contributes to diabetic complications very prominent among which are eye problems (diabetic retinopathy). Tolrestat is intended for oral administration to prevent this. One of its syntheses proceeds by conversion of 6-methoxy-5-(trifluoroniethyl)naphthalene-l-carboxyl-ic acid (6) to its acid chloride followed by carboxamide formation (7) with methyl N-methyl sarcosinate. Reaction of amide 7 with phosphorous pentasulfide produces the methyl ester thioamide which, on treatment with KOH, hydrolyzes to tolrestat (8) 2[. 

Tiazofurine (142) is an antimetabolite with antineoplastic activity. It preferentially affects leukemic lymphocytes over normal cells due to selective activation by formation of its adenine dinucleotide by transformed cells. Of the syntheses available, one starts by conversion of iniidate 138 to methyl 2,5-anhydroallonothioate (139). Next, condensation with ethyl 2-amino-2-cyanoac-etate leads to the thioamide which undergoes thiol addition to the nitrile function to produce the amminothiazolecarboxyester system of 140 directly. Sodium nitrite in aqueous hypophosphorus acid eliminates the superfluous amino group via the diazonium transformation to give 141. This synthesis of tiazofurine (142) concludes by ester amide exchange in methanolic ammonia [48]. 

Altanserin (100) is a representative of the thiaquinazolinones. This serotonin antagonist is said to prevent gastric lesions. One method for preparation of this compound involves first preparation of isothiocyanate derivative 99, by reacting 4-fluorobenzoylpiperidine with 2-bromoethylamine and then converting the intermediate to the isothiocyanate with thionyl chloride and base. Condensation of 99 with methyl anthranilate (98) probably proceeds initially to a thiourea. Cyclization by ester-amide interchange leads to altanserin (100) [28]. 

L-Asparaginyl-L-arginyl-L-valyl-L-tyrosyl-L-valyl-L-histidyl-L-prolyl-L-phenylalanine methyl ester trihydrochloride Angiotensin amide Atropic acid ethyl ester Tilidine HCI Atropine... 

When a cold (-78 °C) solution of the lithium enolate derived from amide 6 is treated successively with a,/ -unsaturated ester 7 and homogeranyl iodide 8, intermediate 9 is produced in 87% yield (see Scheme 2). All of the carbon atoms that will constitute the complex pentacyclic framework of 1 are introduced in this one-pot operation. After some careful experimentation, a three-step reaction sequence was found to be necessary to accomplish the conversion of both the amide and methyl ester functions to aldehyde groups. Thus, a complete reduction of the methyl ester with diisobutylalu-minum hydride (Dibal-H) furnishes hydroxy amide 10 which is then hydrolyzed with potassium hydroxide in aqueous ethanol. After acidification of the saponification mixture, a 1 1 mixture of diastereomeric 5-lactones 11 is obtained in quantitative yield. Under the harsh conditions required to achieve the hydrolysis of the amide in 10, the stereogenic center bearing the benzyloxypropyl side chain epimerized. Nevertheless, this seemingly unfortunate circumstance is ultimately of no consequence because this carbon will eventually become part of the planar azadiene. 

In an effort to make productive use of the undesired C-13 epimer, 100-/ , a process was developed to convert it into the desired isomer 100. To this end, reaction of the lactone enolate derived from 100-) with phenylselenenyl bromide produces an a-selenated lactone which can subsequently be converted to a,) -unsaturated lactone 148 through oxidative syn elimination (91 % overall yield). Interestingly, when 148 is treated sequentially with lithium bis(trimethylsilyl)amide and methanol, the double bond of the unsaturated lactone is shifted, the lactone ring is cleaved, and ) ,y-unsaturated methyl ester alcohol 149 is formed in 94% yield. In light of the constitution of compound 149, we were hopeful that a hydroxyl-directed hydrogenation52 of the trisubstituted double bond might proceed diastereoselectively in the desired direction In the event, however, hydrogenation of 149 in the presence of [Ir(COD)(py)P(Cy)3](PF6)53 produces an equimolar mixture of C-13 epimers in 80 % yield. Sequential methyl ester saponification and lactonization reactions then furnish a separable 1 1 mixture of lactones 100 and 100-) (72% overall yield from 149). 

Monothiocarbonsaure-O-ester-amide werden analog den Carbamidsaure-estem (s. S. 128ff.) durch Lithiumalanat zu N-Methyl-aminen, Alkoholen und Schwefelwasserstoff reduziert ... 

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