Amines, acylation procedure

The choice of the acyl substituent X for Diels-Alder reactions of l-N-acylamino-l,3-butadicnes depends on the particular synthetic problem. The acyl substituent has a moderate effect on the cycloaddition reactivity of these dienes, and also determines what amine unmasking procedures are required. As a result of their stability and the variety of amine deprotection procedures available, " the diene carbamates are the components of choice in most cases. A particularly attractive aspect of the diene synthesis detailed here is the ability to tailor the amino-protecting group... 

There are several chemical reactions that can be used as an alternative to achieve covalent functionalization of CNTs. Two of them are amidation and/or esterification reactions. Both reactions take advantage of the carboxylic groups sitting on the side-walls and tips of CNTs. In particular, they are converted to acyl chloride groups (-C0-C1) via a reaction with thionyl (SO) or oxalyl chloride before adding an alcohol or an amine. This procedure is very versatile and allows the functionalization of CNTs with different entities such as biomolecules [154-156], polymers [157], and organic compounds [158,159] among others. 

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. 

N-Acylation and 3-alkoxycarbonylation reactions may be achieved by conventional acylation procedures. A variety of 3-acyl derivatives 157 can be prepared most conveniently by the treatment of DPPOx 266 with carboxylic acids in the presence of a tertiary amine. tert-Butoxycarbonyl (Boc-Ox, 236) and benzyloxy carbonyl (Cbz-Ox, 267) (Cbz = benzyloxycarbonyl) compounds are of practical use for introduction of nitrogen protecting groups. ... 

The classical Hofmann elimination reaction (which dates back to 1851) has been adapted to the solid phase in combination with the Michael addition. The REM resin, called this way because the resin tinker is REgenerated after product cleavage and functionalized by means of a Michael addition, has been developed to prepare arrays of tertiary amines. The procedure involves acylation of hydroxy-methylpolystyrene with acrylic chloride to furnish the acrylate on resin. Then, a secondary amine, whose substituents offer two potential sites of diversity, is bound by Michael addition. Quaternization of the amine with an alkyl halide (or reductive animation) introduces another site of diversity and activates the tinker to release the amine by a Hofmann elimination with DIEA (Figure 15.14) [127-129]. Additionally, the use of a second basic resin has been described as a source reagent to promote the elimination [130, 131]. 

The most common O- and N-acylation procedures use acylating agents that are more reactive than carboxylic acids or their esters. Acyl chlorides and anhydrides react rapidly with most unhindered alcohols and amines to give esters and amides, respectively. 

The conversion of alcohols to esters by O-acylation and of amines to amides by N-acylation are fundamental organic reactions. These reactions are the reverse of the hydrolytic procedures discussed in the preceding sections. Section 3.4 in Part B discusses these reactions from the point of view of synthetic applications and methods. 

In the acylation of enamines, the weakly basic acylated enamine does not absorb the acid formed. Consequently, one must employ 2 equivalents of the enamine or use a second tertiary amine to absorb the acid liberated. In the procedure, triethylamine is employed to absorb the hydrochloric acid. 

In a related procedure, even benzene and substituted benzenes (e.g., PhMe, PhCl, xylenes) can be converted to phenols in good yields with sodium perborate F3CS020H. " Aromatic amines, N-acyl amines, and phenols were hydroxylated with H2O2 in SbFs—HF. Pyridine and quinoline were converted to their 2-acetoxy derivatives in high yields with acetyl hypofluorite AcOF at -75°C. ... 

Enantiopure N,N -hnked oligoureas were originally described in 1995 by Burgess and coworkers as novel peptide backbone mimetics [271, 272]. Several synthetic approaches have been reported, all of which involve sequential acylation and amine deprotection cycles using appropriately protected carbonyl synthons [83, 271, 272, 274, 286-288]. Although elongation can be performed in solution, most of the synthetic procedures are elaborated on solid supports starting from Rink s... 

Section A of Scheme 10.15 contains a number of examples of Curtius rearrangements. Entry 1 is an example carried out in a nonnucleophilic solvent, permitting isolation of the isocyanate. Entries 2 and 3 involve isolation of the amine after hydrolysis of the isocyanate. In Entry 2, the dihydrazide intermediate is isolated as a solid and diazotized in aqueous solution, from which the amine is isolated as the dihydrochloride. Entry 3 is an example of the mixed anhydride procedure (see p. 948). The first stage of the reaction is carried out in acetone and the thermolysis of the acyl azide is done in refluxing toluene. The crude isocyanate is then hydrolyzed in acidic water. Entry 4 is a reaction that demonstrates the retention of configuration during rearrangement. 

Because the reaction of an amine with an acyl chloride is much faster than the hydrolysis of the acyl chloride, the reaction can usually be carried out in an aqueous alkali solution. This is well known as the Schotten-Baumann procedure.6 For example, a number of N-acyl taxol analogs have been prepared under Schotten-Baumann conditions by the reaction of A-debenzoyltaxol with various acid chlorides (Eq. 9.4).7 Highly purified /V-long-chain-acyl neutral amino acids such as potassium AMauroyTy-aminobutyrate, useful as surfactants for detergent... 

In this series, too, replacement of the N-methyl by a group such as cyclopropylmethyl leads to a compound with reduced abuse potential by virtue of mixed agonist-antagonist action. To accomplish this, reduction of 24 followed by reaction with tertiary butylmagnesium chloride gives the tertiary carbinol 27. The N-methyl group is then removed by the classic von Braun procedure. Thus, reaction with cyanogen bromide leads to the N-cyano derivative (28) hydrolysis affords the secondary amine 29. (One of the more efficient demethylation procedures, such as reaction with ethyl chloroformate would presumably be used today.) Acylation with cyclopropylcarbonyl chloride then leads to the amide 30. Reduction with lithium aluminum hydride (31) followed by demethylation of the phenolic ether affords buprenorphine (32).9... 

Modification of amines with maleic anhydride is done essentially the same as that described for succinic anhydride (this section, Part A), except the pH of the reaction should be kept alkaline (pH 8-9) at all times to prevent unwanted de-acylation. Deblocking of maleylated amines can be accomplished according to the following procedure of Butler et al. (1967). 

Methods for the A-acylation of similar heterocycles, such as simple thiazolidinethiones, have been reported since 1977, namely acyl chlorides in miscellaneous conditions,586 or carboxylic acids under DCC-activation.60,61 However the easiest and most effective method involves acyl chlorides or carboxylic anhydrides in the presence of an amine.47 Applying that procedure on carbohydrate scaffolds Rollin and co-workers62 reported the synthesis of diverse /V-acylated OZTs. The reactions were performed with good yields and the /V-selective acylation was ascertained by NMR— namely the thiocarbonyl 13C chemical shift (Scheme 41). Thanks to the dual nature of the carbanion drifting in the reaction,596 60 no competitive formation of the thioester, as mentioned by Plusquellec el al. in the case of benzothiazole, was observed. 

The simplicity of the two-phase modification of the Gabriel synthesis of primary amines, via the N-alkylation of potassium phthalimide, makes the procedure considerably more convenient than the traditional method, which normally requires the use of anhydrous dipolar aprolic solvents. The reaction can be conducted under solid liquid conditions using potassium hydroxide in toluene [25], or with preformed potassium phthalimide [26, 27] (cf ref. 28). As is normal for acylation reactions, relatively mild conditions are required for the preparation of the A-ethoxycarbonyl derivative [29], whereas a reaction temperature of 100°C is generally used for N-alkylation (Table 5.16). The reaction time for the soliddiquid two-phase system can be reduced dramatically with retention of the high yields, when the reaction mixture is subjected to microwave irradiation [30]. 

This is a simple procedure for the enzymatic resolution of a secondary amine. The acylating agent can be modified by altering the substitution on the phenol ring. This tuning of the reactivity and selectivity should allow other amines to be resolved using a similar approach. 

The acylation and amination reactions to prepare the dendrimer start with the amine slides prepared according to the above procedure. 

The A -methyl derivative (32) was obtained from 31 via a Leuckart reaction and isolated as its hydrochloride 32 is also formed in the Hoffmann-Lbflfterreaction(photolysisinsulfuricacid)ofthei r-chloramine (33), since after separation of secondary amines and addition of methyl iodide a 10% yield of the methiodide (34) was obtained. The secondary amine (31) was also converted to its A-acyl and JV -nitroso derivatives (35-37) and (38), respectively, by conventional procedures. Free-radical chlorination of 37 gave the ca o-2-chloro derivative (39) and... 

Chirality derived from the readily accessible a-amino acids has been incorporated into the side chains of aza and diaza macrocyclic polyethers. A number of procedures suitable for peptide synthesis have proved (178) to be unsuitable for acylating the relatively unreactive secondary amine groups of aza crown ethers. Eventually, it was discovered that mixed anhydrides of diphenylphos-phinic acid and alkoxycarbonyl-L-alanine derivatives do yield amides, which can be reduced to the corresponding amines, e.g., l-172. By contrast, the corresponding bisamides of diaza-15-crown-S derivatives could not be reduced and so an alternative approach, involving the use of chiral A-chloroacetamido alcohols derived from a-amino acids, has been employed (178) in the synthesis of chiral receptors, such as ll-173 to ll-175, based on this constitution. 

Kim et al. have developed a practical procedure for the DKR of primary amines illustrated by substrate 56c (Scheme 2.28). They employed a supported palladium nanocatalyst as the racemization catalyst and commercially available CALB as the enantioselective catalyst for acylation of the amine using ethyl methoxyacetate as the acyl donor. High yields and enantiomeric excesses were achieved [30]. 

This process has many benefits in the context of green chemistry it involves two enzymatic steps, in a one-pot procedure, in water as solvent at ambient temperature. It has one shortcoming, however-penicillin acylase generally works well only with amines containing an aromatic moiety and poor enantioselectivities are often observed with simple aliphatic amines. Hence, for the easy-on/easy-off resolution of aliphatic amines a hybrid form was developed in which a hpase [Candida antarctica hpase B (CALB)] was used for the acylation step and peniciUin acylase for the deacylahon step [22]. The structure of the acyl donor was also optimized to combine a high enanhoselectivity in the first step with facile deacylation in the second step. It was found that pyridyl-3-acetic acid esters gave optimum results (see Scheme 6.8). 

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