Ethyl chloroformate acid anhydride synthesis

The synthesis of key intermediate 12, in optically active form, commences with the resolution of racemic trans-2,3-epoxybutyric acid (27), a substance readily obtained by epoxidation of crotonic acid (26) (see Scheme 5). Treatment of racemic 27 with enantio-merically pure (S)-(-)-1 -a-napthylethylamine affords a 1 1 mixture of diastereomeric ammonium salts which can be resolved by recrystallization from absolute ethanol. Acidification of the resolved diastereomeric ammonium salts with methanesulfonic acid and extraction furnishes both epoxy acid enantiomers in eantiomerically pure form. Because the optical rotation and absolute configuration of one of the antipodes was known, the identity of enantiomerically pure epoxy acid, (+)-27, with the absolute configuration required for a synthesis of erythronolide B, could be confirmed. Sequential treatment of (+)-27 with ethyl chloroformate, excess sodium boro-hydride, and 2-methoxypropene with a trace of phosphorous oxychloride affords protected intermediate 28 in an overall yield of 76%. The action of ethyl chloroformate on carboxylic acid (+)-27 affords a mixed carbonic anhydride which is subsequently reduced by sodium borohydride to a primary alcohol. Protection of the primary hydroxyl group in the form of a mixed ketal is achieved easily with 2-methoxypropene and a catalytic amount of phosphorous oxychloride. 

A number of 2,3-fused chromones have been prepared from ethyl chloroformate and acetylsalicylic acid, a source of the mixed anhydride of formic and salicylic acids, and piperidinocycloalkenes (69JCS(C)935). A plausible mechanism is outlined in Scheme 165. It has not proved possible to isolate the chromanone (460) but the formation of 3-acetyl-2-methylchromone from 2-pyrrolidinopropene lends support to the intermediacy of the chromanone. The migration of the acyl group from oxygen to carbon is supported by the synthesis of 3-benzoyl-2-methylchromone rather than 3-acetylflavone from benzoylsalicylic acid and the pyrrolidinopropene. 

The cyclohexene 121, which was readily accessible from the Diels-Alder reaction of methyl hexa-3,5-dienoate and 3,4-methylenedioxy-(3-nitrostyrene (108), served as the starting point for another formal total synthesis of ( )-lycorine (1) (Scheme 11) (113). In the event dissolving metal reduction of 121 with zinc followed by reduction of the intermediate cyclic hydroxamic acid with lithium diethoxyaluminum hydride provided the secondary amine 122. Transformation of 122 to the tetracyclic lactam 123 was achieved by sequential treatment with ethyl chloroformate and Bischler-Napieralski cyclization of the resulting carbamate with phosphorus oxychloride. Since attempts to effect cleanly the direct allylic oxidation of 123 to provide an intermediate suitable for subsequent elaboration to ( )-lycorine (1) were unsuccessful, a stepwise protocol was devised. Namely, addition of phenylselenyl bromide to 123 in acetic acid followed by hydrolysis of the intermediate acetates gave a mixture of two hydroxy se-lenides. Oxidative elimination of phenylselenous acid from the minor product afforded the allylic alcohol 124, whereas the major hydroxy selenide was resistant to oxidation and elimination. When 124 was treated with a small amount of acetic anhydride and sulfuric acid in acetic acid, the main product was the rearranged acetate 67, which had been previously converted to ( )-lycorine (108). 

For a carboxylic acid and an amine to form an amide, the carboxylic acid usually must be activated that is, it must be converted to a more reactive functional group. Conversion to an acyl chloride is a common way to accomplish this for normal organic reactions (see Chapter 19). However, acyl chlorides are quite reactive and do not give high enough yields in peptide synthesis because of side reactions. Therefore, milder procedures for forming the amide bond are usually employed. In one method the carboxylic acid is reacted with ethyl chloroformate (a half acyl chloride, half ester of carbonic acid) to produce an anhydride. Treatment of this anhydride with an amine results in the formation of an amide ... 

MnClj. The chloromanganese reagents can be used in THF, a more satisfactory solvent for the synthesis of ketones from mixed carbonic-carboxylic anhydrides (prepared by the reaction of carboxylic acids with ethyl chloroformate). 

Jacobi s synthesis of ( )-paniculide-A involves an intramolecular Diels-Alder reaction of the alkynic ketone (31). This compound was prepared in >90% yield (Scheme 9) by acylation of a lithium alkynide with the A7-methoxy-A7-methylamide (30). Addition of the anion to other derivatives related to (30) such as an acid chloride, a trifluoroacetic mixed anhydride, an acyl imidazole, S-(2-pyridyl) thiolates and a mixed carbonic anhydride (from ethyl chloroformate) led to either bis-addition or to proton abstraction. Notice should be made of the stability exhibited by the A7-methoxy-A7-methylamide group while the oxa-zole moiety was being introduced. ... 

Primary and secondary amides and thioamides react with alkyl chlorofoimates with loss of CO2 or COS, forming iminium chlorides (82 equation 52). In some cases this method is complementary to the Pinner imido ester hydrochloride synthesis. The iminium salt (83 Scheme 6) formed by action of ethyl chloroformate on DMF is labile and decomposes rapidly to ethyl chloride. If the reaction is performed in the presence of NaBp4, the iminium salt (85) is isolable. Aryl chlorofoimates react in the same fashion with DMF or DMA, but in these cases the aryloxymethyleneiminium compounds are fairly stable, so this reaction is an important method for the preparation of compounds of this type. - Succinic acid monoamides, phthalic acid monoamides and related compounds are cyclized to iminium salts (86 equation 53) by treatment with acetic anhydride and HC104. ° With the aid of trifluoromethanesulfonic anhydride lactams and amides can be converted to dication ether salts (87) and (88 Scheme 7).22i.222... 

Mixed anhydride synthesis. A method widfely used for the synthesis of peptides provides a general method of acylation, illustrated by the benzoylation of diethyl malonate. Benzoic acid is converted into the triethylamine salt in toluene, and the solution is treated at 0 with ethyl chloroformate to form the mixed benzoic-carbonic anhydride, with precipitation of triethylamine hydrochloride. The second component, ethoxymagnesium malonic ester, is prepared from diethyl malonate in ethanol-ether... 

The Curtius rearrangement has been extensively utilized for the synthesis of numerous cyclo-propylamines 4 from cyclopropanecarboxylic acids 1. The necessary acyl azides 2 are most conveniently obtained by reaction of sodium azide with the mixed anhydride of the cyclopropanecarboxylic acid and ethyl chloroformate. ... 

The synthesis of phosphinate derivatives 32 described by Pompei was performed by coupling of the key macrocyclic acid 30 [35, 39], with racemic phosphinic acid 31 (Scheme 5) [34], This coupling occurred by converting the carboxylic acid of pyroUdine ring with ethyl chloroformate into an anhydride intermediate which was subsequently trapped by the amino function of phosphinic acid derivatives. 

N-(s-Triazoi-4-yl)phenylacetamidine refluxed 12 hrs. with an equimolar amount of ethyl chloroformate in dry nitromethane or acetonitrile 3-phenyl-l,2,4-triazole. Y 91%. - Other acylating agents sudi as acetic anhydride, carboxylic acids, or HCl may be used in place of ethyl diloroformate. F. e. s. H. G. O. Becker et al., J. pr. 311, 471 (1969) synthesis of 1,3,4-oxadiazoles cf. ibid. 311, 646. 

The amino group in Z-Ala is protected as the nonnucleophilic amide half of a carbamate ester. The carboxyl group can be activated without reacting with the protected amino group. In the solution-phase synthesis, the carboxyl group is activated by treatment with ethyl chloroformate. The product is a mixed anhydride of the amino acid and carbonic acid. It is strongly activated toward nucleophilic attack. 

Another synthetic approach to acyl azides was reported by Weinstock one decade earlier. In this methodology, acyl azides are prepared via carboxylic-carbonic anhydrides. Generally, carboxylic acids are treated with ethyl chloroformate, generating mixed anhydrides which are trapped in situ by sodium azide. This sinple strategy was applied recently in the synthesis of ( )-spisulosine fScheme 4.21 After only 5 min in the presence of ethyl chloroformate, the appropriate carboxylic acid 58 was next treated with sodium azide. The intermediate ene-isocyanate 59 was obtained after heating, and this latter is finally hydrolyzed by water. The corresponding methyl ketone 60 was isolated in 40% overall yield. 

A convenient synthesis of anhydrides has been described by the reaction of potassium or sodium salts of carboxylic acids with activating halides (ethyl chloroformate, cyanuric chloride and benzyl chloroformate) in acetonitrile in the presence of 18-crown-6. Using this procedure, cinnamic acid, p-nitrobenzoic acid, benzoic acid, acetic acid and propionic acid are also converted into their anhydrides (Scheme 30). 

In the synthesis of evodiamine effected by Asahina and Ohta,i N-methylanthranilic acid was converted by ethyl chloroformate into N-methylisatoic anhydride, which, on treatment with 8-jS-aminoethylindole, furnished 8-jS-o-methylaminobenzoylaminoethylindole (III), and this with ethyl orthoformate at 175-180° gave dZ-evodiamine, m.p. 278°, convertible by boiling alcoholic hydrogen chloride into fsoevodiamine, m.p. 147°, as shown above. 

The mechanism of the condensation in Part D probably involves thioformylation of the metallated isocyanoacetate followed by intramolecular 1,1-addition of the tautomeric enethiol to the isonitrile. This thi2izole synthesis is analogous to the formation of oxazoles from acylation of metallated isonitriles with acid chlorides or anhydrides. " Interestingly, ethyl formate does not react with isocyanoacetate under the conditions of this procedure. Ethyl and methyl isocyanoacetate have been prepared in a similar manner by dehydration of the corresponding N-formylglycine esters with phosgene and trichloromethyl chloroformate, respectively. The phosphoryl chloride method described here was provided to the submitters by Professor U. Schollkopf and is based on the procedure of Bohme and Fuchs. The preparation of O-ethyl thioformate in Part C was developed from a report by Ohno, Koi/.uma, and Tsuchihaski. " ... 

Alkyl-substituted oxazoles have been found to react with maleic acid or its anhydride in a diene synthesis to yield substituted pyridine readily converted to pyridoxine (39). In this route, ethyl d, 1-alaninate hydrochloride is treated with formic-acetic anhydride to yield ethyl N-formyl d,1-alaninate (78%). This compound is refluxed in chloroform with phosphorous pentoxide (40), quenched with aqueous potassium hydroxide, and the organic layer distilled to give 4-methyl-5-ethoxyoxazole (I) (60%). The resulting oxazole (I) is condensed readily with a number of appropriate dienophiles to form 2-methyl-3-hydroxy-4,5-disubstituted-pyridines containing substituents (III, a, b, c) which could be converted to pyridoxine as follows ... 

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