N-Acylation

Maggini M, Karlsson A, Pasimeni L, Scorrano G, Prato M and Valli L 1994 Synthesis of N-acylated... 

Then N-Boc-O-benzylserine is coupled to the free amino group with DCC. This concludes one cycle (N° -deprotection, neutralization, coupling) in solid-phase synthesis. All three steps can be driven to very high total yields (< 99.5%) since excesses of Boc-amino acids and DCC (about fourfold) in CHjClj can be used and since side-reactions which lead to soluble products do not lower the yield of condensation product. One side-reaction in DCC-promoted condensations leads to N-acylated ureas. These products will remain in solution and not reaa with the polymer-bound amine. At the end of the reaction time, the polymer is filtered off and washed. The times consumed for 99% completion of condensation vary from 5 min for small amino acids to several hours for a bulky amino acid, e.g. Boc-Ile, with other bulky amino acids on a resin. A new cycle can begin without any workup problems (R.B. Merrifield, 1969 B.W. Erickson, 1976 M. Bodanszky, 1976). 

Mercapto-imida2oliuin inner salts have been reported to rearrange under the influence of hydrochloric acid, producing S-aminothiazolium chlorides (Scheme 25) (36). Their N-acylated derivatives are obtained by cyclization of N-thiobenzoyl alkylaminoacetonitriles, effected with acyl or sulfonyl halides (Scheme 26) (34, 35). 

The 5-amino-THISs are very strong bases (35). The hydrochlorides, therefore, have not yet been deprotonized successfully. However, the decreased basicity of the N-acylated derivatives makes these readily accessible from their hydrochlorides (Scheme 28). 

Electrophilic aromatic substitution (Sec tion 22 14) Arylamines are very reac tive toward electrophilic aromatic sub stitution It IS customary to protect arylamines as their N acyl derivatives before carrying out ring nitration chio rination bromination sulfonation or Friedel-Crafts reactions... 

N-Acylation is readily carried out by reaction of the alkaU metal salts with the appropriate acid chloride. C-Acylation of pyrroles carrying negative substituents occurs in the presence of Friedel-Crafts catalysts. Pyrrole and alkylpyrroles can be acylated noncatalyticaHy with an acid chloride or an acid anhydride. The formation of trichloromethyl 2-pyrryl ketone [35302-72-8] (20, R = CCI3) is a particularly useful procedure because the ketonic product can be readily converted to the corresponding pyrrolecarboxyUc acid or ester by treatment with aqueous base or alcohoHc base, respectively (31). 

Treatment of 2-pyrrohdinone with an acid anhydride or acyl hahde results in N-acylation. 

Isoquinoline can be reduced quantitatively over platinum in acidic media to a mixture of i j -decahydroisoquinoline [2744-08-3] and /n j -decahydroisoquinoline [2744-09-4] (32). Hydrogenation with platinum oxide in strong acid, but under mild conditions, selectively reduces the benzene ring and leads to a 90% yield of 5,6,7,8-tetrahydroisoquinoline [36556-06-6] (32,33). Sodium hydride, in dipolar aprotic solvents like hexamethylphosphoric triamide, reduces isoquinoline in quantitative yield to the sodium adduct [81045-34-3] (25) (152). The adduct reacts with acid chlorides or anhydrides to give N-acyl derivatives which are converted to 4-substituted 1,2-dihydroisoquinolines. Sodium borohydride and carboxylic acids combine to provide a one-step reduction—alkylation (35). Sodium cyanoborohydride reduces isoquinoline under similar conditions without N-alkylation to give... 

Bischler-ISlapieralski Reaction. This synthetic method involves the cyclodehydration of N-acyl derivatives of p-phenethjlamines (26) to... 

In the piepaiation of ioveisol (12) (41), the key intermediate (23) is prepared from the diacid (20) by the action of thionyl chloride followed by 3-amino-l,2-propanediol. The alcohol groups of (23) are protected as the acetates (25), which is then N-acylated with acetoxyacetyl chloride and deprotected in aqueous methanol with sodium hydroxide to yield (26). N-alkylation of (26) produces ioversol (12). 

A mild and effective method for obtaining N- acyl- and N- alkyl-pyrroles and -indoles is to carry out these reactions under phase-transfer conditions (80JOC3172). For example, A-benzenesulfonylpyrrole is best prepared from pyrrole under phase-transfer conditions rather than by intermediate generation of the potassium salt (81TL4901). In this case the softer nature of the tetraalkylammonium cation facilitates reaction on nitrogen. The thallium salts of indoles prepared by reaction with thallium(I) ethoxide, a benzene-soluble liquid. 

Azoles containing a free NH group react comparatively readily with acyl halides. N-Acyl-pyrazoles, -imidazoles, etc. can be prepared by reaction sequences of either type (66) -> (67) or type (70)->(71) or (72). Such reactions have been carried out with benzoyl halides, sulfonyl halides, isocyanates, isothiocyanates and chloroformates. Reactions occur under Schotten-Baumann conditions or in inert solvents. When two isomeric products could result, only the thermodynamically stable one is usually obtained because the acylation reactions are reversible and the products interconvert readily. Thus benzotriazole forms 1-acyl derivatives (99) which preserve the Kekule resonance of the benzene ring and are therefore more stable than the isomeric 2-acyl derivatives. Acylation of pyrazoles also usually gives the more stable isomer as the sole product (66AHCi6)347). The imidazole-catalyzed hydrolysis of esters can be classified as an electrophilic attack on the multiply bonded imidazole nitrogen. 

N-Inversion in azetidine and azetidin-2-one is rapid, even at —77 and -40 °C, respectively (B-73NMR144). Again, halo substituents on nitrogen drastically slow the inversion rate, so that Af-chloro-2-methylazetidine can be separated into two diastereomers (b-77SH(1)54). Substituent effects on N-inversion are much the same as in the aziridines Af-aryl and N- acyl... 

Azete, trisdimethylamino-isolation, 7, 278 Azetes, 7, 237-284, 278-284 benzo fused, 7, 278 benzodiazepine fused applications, 7, 284 fused ring, 7, 341-362 structure, 7, 360 2,3-naphtho fusion, 7, 278 reactivity, 7, 279 structure, 7, 278 synthesis, 7, 282-283 Azetidine, acylring expansion, 7, 241 synthesis, 7, 246 Azetidine, 3-acyl-irradiation, 7, 239 synthesis, 7, 246 Azetidine, N-acyl-synthesis, 7, 245 Azetidine, alkyl-synthesis, 7, 246 Azetidine, 3-alkylthio-synthesis, 7, 246 Azetidine, 3-amino-synthesis, 7, 246 Azetidine, N-amino-oxidation, 7, 241 synthesis, 7, 246 Azetidine, aryl-synthesis, 7, 246... 

Dibenz[6,/]azepine, 5-acetyl-lO-cyano-reduction, 7, 517 Dibenz[6,/]azepine, 1-acyl UV spectra, 7, 501-502 Dibenz[6,/]azepine, N-acyl-10,11-dihydro-NMR, 7, 499... 

Dibenz[6, ejazepines conformation, 7, 499 11H-Dibenz[6, ejazepines oxidation, 7, 525 reduction, 7, 517 synthesis, 7, 532, 533 Dibenz[6,/]azepines N-acyl derivatives UV spectra conformation, 7, 499 mass spectrum, 7, 501 nitroxide... 

Imidazole, 4-acetyl-5-methyl-2-phenyl-synthesis, 5, 475 Imidazole, 1-acyl-reactions, 5, 452 rearrangement, 5, 379 Imidazole, 2-acyl-synthesis, 5, 392, 402, 408 Imidazole, 4-acyl-synthesis, 5, 468 Imidazole, C-acyl-UV spectra, 5, 356 Imidazole, N-acyl-hydrolysis rate constant, 5, 350 reactions, 5, 451-453 synthesis, 5, 54, 390-393 Imidazole, alkenyl-oxidation, 5, 437 polymerization, 5, 437 Imidazole, 1-alkoxycarbonyl-decarboxylation, 5, 453 Imidazole, 2-alkoxy-l-methyl-reactions, 5, 102 thermal rearrangement, 5, 443 Imidazole, 4-alkoxymethyl-synthesis, 5, 480 Imidazole, alkyl-oxidation, 5, 430 synthesis, 5, 484 UV spectra, 5, 355 Imidazole, 1-alkyl-alkylation, 5, 73 bromination, 5, 398, 399 HNMR, 5, 353 synthesis, 5, 383 thermal rearrangement, 5, 363 Imidazole, 2-alkyl-reactions, 5, 88 synthesis, 5, 469... 

Pyridinium bromide, N-phenacyl-NMR, 2, 121 reactions, 2, 336 Pyridinium cations metabolism, 1, 234 reactivity, 2, 167 Pyridinium chloride hydrogenation, 2, 284 Pyridinium chloride, N-acyl-as acylating agent, 2, 180 Pyridinium chloride, cetyl-as antiseptic, 2, 519... 

MADELUNG IndotoSynthesis (ndole synthesis by cydizatlon ol N-acyl-o-tokiidines. 

Two disadvantages are associated with the use of S-acetyl or 5-benzoyl derivatives in peptide syntheses (a) base-catalyzed hydrolysis of 5-acetyl- and 5-benzoylcys-teine occurs with /S-elimination to give olefinic side products, CH2=C-(NHPG)CO—(b) the yields of peptides formed by coupling an unprotected amino group in an 5-acylcysteine are low because of prior S-N acyl migration. ... 

Na/NH3, -30°, 3 min, 1(X)% yield. This protective group is stable to acidic hydrolysis (4.5 N HBr/HOAc 1 N HCV, CF3CO2H, reflux). There is no evidence of S N acyl migration in 5-(A-ethylcarbamates) (RS = cysteinyl). Oxidation of 5-(A-ethylcarbamoyl)cysteine with performic acid yields cysteic acid. ... 

Carbamates can be used as protective groups for ammo acids to minimize race-mization in peptide synthesis. Raccmi/ation occurs during the base-catalyzed coupling reaction of an W-protected, catboxyl-uc ivated amino acid, and takes place in the intermediate oxazolone that foro S readily from an N-acyl protected amino... 

Diethyl aminomalonate is a useful intermediate, lending itself to N-acylation the N-acyl derivatives may be alkylated by procedures as established for syntheses via malonic ester. 

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. 

Although the previous two sections of this chapter emphasized hydrolytic processes, two mechanisms that led to O- or N-acylation were considered. In the discussion of acid-catalyzed ester hydrolysis, it was pointed out that this reaction is reversible (p. 475). Thus, it is possible to acylate alcohols by reaction with a carboxyhc acid. To drive the reaction forward, the alcohol is usually used in large excess, and it may also be necessary to remove water as it is formed. This can be done by azeotropic distillation in some cases. 

The second reaction that should be recalled is the aminolysis of esters (p. 479). This reaction leads to the formation of amides by N-acylation ... 

The most common O- and N-acylation procedures use acylating agents that are more reactive than caiboxylic acids or their esters. Carboxylic acid chlorides and anhydrides react rapidly with most unhindered hydroxy and amino groups to give esters and amides, respectively ... 

From semiamidals, the correspondmg tnfluoromethyl substituted N-acyl mines [25, 28], 1,3-diambutadienes [27], N-sulfonyl mines [5, 29], N sulfinyl mines [30], and N-phosphoryl mines [31] can be obtamed in high yields on reaction with powerful dehydratmg realms like POC -pyndine or tnfluoroacetic anhydnde-pyndme [2, 5]... 

Halogen-free A/-acyl aldimines and N-acyl ketiimnes tautomenze readily to give enamides [J6] In contrast, perfluonnatedyV-acylimines are stable compounds These electron-deficient itnmes not only exhibit high thermal stability but also show umque properties both as electrophiles and as strongly polanzed hetero-1,3-dienes... 

The preparation of enamines by reduction of aromatic heterocyclic bases and their quaternary salts or of lactams is not the most useful approach (97). The lithium aluminum hydride reduction of N-acyl enamines has been used with both fruitful and unsuccessful results. A series of 3-N-acetyl -d -cholestenes (104) has been prepared by desulfurization of the appropriate thiazolidine (105) (98,99). Lithium aluminum hydride reduction of the... 

N-acyl enaminc (104, R = CHjCHj) gave an unstable enamine (106) which decomposed readily to 3-cholestanone. The steroidal N-acetyl enamines (107 and 108, R = C HjCHj) can be reduced by lithium aluminum hydride in tctrahydrofuran to the corresponding enamines (109, R = CJH5CH2) in 90 and 68% yield, respectively 100). Attempts to reduce the enamide (107, R = CH3) led to the formation of the impure enamine (109, R = CHj), which decomposed to the hydroxy ketone (110). 

The acylation of enamino ketones can take place on oxygen or on carbon. While reaction at nitrogen is a possibility, the N-acylated products are themselves acylating agents, and further reaction normally takes place. The first reported acylation of enamino ketones (72) was that of 129, prepared by acylation of the enamine (113), which was shown to have undergone O acylation because on mild hydrolysis the enol ester (130) could be isolated. A similar reaction took place with other aliphatic acid chlorides (80) and with dibasic acid chlorides [e.g., with succinyl chloride to give 118 above]. 

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