Amine with esters

The reaction of ammonia and amines with esters follows the same general mech anistic course as other nucleophilic acyl substitution reactions (Figure 20 6) A tetrahe dral intermediate is formed m the first stage of the process and dissociates m the second stage... 

The nitrogen atom in a-ferrocenylalkylamines generally shows the same reaction pattern as that in other amines alkylation and acylation do not provide synthetic problems. Due to the high stability of the a-ferrocenylalkyl carbocations, ammonium salts readily lose amine and are, therefore, important synthetic intermediates. Acylation of primary amines with esters of formic acid gives the formamides, which can be dehydrated to isocyanides by the standard POClj/diisopropylamine technique (Fig. 4-16) [92]. Chiral isocyanides are obtained from chiral amines without any racemization during the reaction sequence. The isocyanides undergo normal a-addition at the isocyanide carbon, but could not be deprotonated at the a-carbon by even strong bases. This deviation from the normal reactivity of isocyanides prompted us to study the electrochemistry of these compounds, but no abnormal redox behaviour, compared with that of other ferrocene derivatives, was detected [93]. The isocyanides form chromium pentacarbonyl complexes on treatment with Cr(CO)s(THF) (Fig. 4-16) and electrochemistry demonstrated that there is no electronic interaction between the two metal centres. 

Another useful synthetic route to amides 25 utilized the methyl ester (12 R = Me) prepared by ring expansion of the corresponding benziso-thiazoline ester 8 (R = OMe).9 Methylation of 12 produced ester 28. Combination of various amines with ester 28, or the corresponding ethyl ester, gives analogs of compound 25.7,817,18 The use of heterocyclic amines in this reaction has produced the N-heterocyclic amides sudoxicam (20)19 and piroxicam (29),2 0 21 potent anti-inflammatory agents that are discussed more fully in Section II,D. 

Hydroxypyridine is generally applicable for the reaction of strongly basic amines with esters. It is easily recovered for further use because of its high solubility in water. 

BASF researchers developed the lipase-catalyzed KR of various amines with esters of methoxyacetic acid in methyl tert-butyl ether (MTBE) [129,130] to produce chiral amines at multi-1000tonsyear scale [131],... 

A search of the literature on the reactions of primary and secondary amines with esters, amides, and imides reveals that generally SB-catalyzed aminolysis term in the rate law appears only when the rate law contains an additional GB-catalyzed term. It is also quite conunon that the rate law contains only a GB-catalyzed term. But it is almost rare or nonexistent that a rate law does not contain a GB-catalyzed term but contains an SB-catalyzed term. These general observations can be easily understood in terms of a stepwise mechanism similar to Scheme 2.32 with HNu = RNH2. However, a recent report on the kinetic studies of the cleavage of A-phthaloylglysine (46) in the buffers of hydrazine shows that pseudo-first-order rate constants (k bs) for the cleavage of 46 follow Equation 2.40 ... 

Cannot be used for alcohols, phenols or amines, with all of which it combines. Not advisable for acidic liquids, as ordinary calcium chloride always contains some calcium hydroxide owing to partial hydrolysis during preparation. Usually used for alcohols (see p. 88). Cannot be used for acidic compounds, nor for esters, which it would hydrolyse. 

Primary and secondary amines also react with epoxides (or in situ produced episulfides )r aziridines)to /J-hydroxyamines (or /J-mercaptoamines or 1,2-diamines). The Michael type iddition of amines to activated C—C double bonds is also a useful synthetic reaction. Rnally unines react readily with. carbonyl compounds to form imines and enamines and with carbo-tylic acid chlorides or esters to give amides which can be reduced to amines with LiAlH (p. Ilf.). All these reactions are often applied in synthesis to produce polycyclic alkaloids with itrogen bridgeheads (J.W. Huffman, 1967) G. Stork, 1963 S.S. Klioze, 1975). 

FIGURE 20 6 Mechanism of amide formation in the reac tion of a secondary amine with an ethyl ester... 

Amides are readily prepared by acylation of ammonia and amines with acyl chlorides acid anhydrides or esters... 

Section 20 14 Amides are normally prepared by the reaction of amines with acyl chlo rides anhydrides or esters... 

Aluminum chloride [7446-70-0] is a useful catalyst in the reaction of aromatic amines with ethyleneknine (76). SoHd catalysts promote the reaction of ethyleneknine with ammonia in the gas phase to give ethylenediamine (77). Not only ammonia and amines, but also hydrazine [302-01-2] (78), hydrazoic acid [7782-79-8] (79—82), alkyl azidoformates (83), and acid amides, eg, sulfonamides (84) or 2,4-dioxopyrimidines (85), have been used as ring-opening reagents for ethyleneknine with nitrogen being the nucleophilic center (1). The 2-oxopiperazine skeleton has been synthesized from a-amino acid esters and ethyleneknine (86—89). 

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). 

Telomerization Reactions. Butadiene can react readily with a number of chain-transfer agents to undergo telomerization reactions. The more often studied reagents are carbon dioxide (167—178), water (179—181), ammonia (182), alcohols (183—185), amines (186), acetic acid (187), water and CO2 (188), ammonia and CO2 (189), epoxide and CO2 (190), mercaptans (191), and other systems (171). These reactions have been widely studied and used in making unsaturated lactones, alcohols, amines, ethers, esters, and many other compounds. 

Unprotected racemic amines can be resolved by enantioselective acylations with activated esters (110,111). This approach is based on the discovery that enantioselectivity of some enzymes strongly depends on the nature of the reaction medium. For example, the enantioselectivity factor (defined as the ratio of the initial rates for (3)- and (R)-isomers) of subtiHsin in the acylation of CX-methyl-ben zyl amine with tritiuoroethyl butyrate varies from 0.95 in toluene to 7.7 in 3-methyl-3-pentanol (110). The latter solvent has been used for enantioselective resolutions of a number of racemic amines (110). 

Esters undergo hydrolysis and conversion to amides under the usual conditions, and amide side chains have also been formed from the acid and amine with DCCI. Acids have been formed from the corresponding spirohydantoins via ureido derivatives (Section 2.15.15.6.1), and undergo decarboxylation in the usual manner. 

Sodium (metal). Used as a fine wire or as chips, for more completely drying ethers, saturated hydrocarbons and aromatic hydrocarbons which have been partially dried (for example with calcium chloride or magnesium sulfate). Unsuitable for acids, alcohols, alkyl halides, aldehydes, ketones, amines and esters. Reacts violently if water is present and can cause a fire with highly flammable liquids. 

Reaction of amines with acyl chlorides (Section 20.4) Amines are converted to amides on reaction with acyl chlorides. Other acylating agents, such as carboxylic acid anhydrides and esters, may also be used but are less reactive. 

The choline ester is prepared by treating the 2-bromoethyl ester with trimethyl-amine. The ester is cleaved with butyrylcholine esterase (pH 6, 0.05 M phosphate buffer, rt, 50-95% yield). As with the morpholinoethyl ester, the choline ester imparts greater solubility to the C-terminal end of very hydrophobic peptides, thus improving the ability to cleave enzymatically the C-terminal ester. ... 

Preparation of the key tropine is achieved by any one of several variations on the method first developed by Robinson, which involves reaction of a primary amine with dihydroxyacetone and glyoxal. Reduction of the carbonyl group in the product (86) followed by acylation affords the aminoester (88). Transesterification with ester aldehyde 89... 

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