Amides reaction with, phosgene

Specialty Isocyanates. Acyl isocyanates, extensively used in synthetic appHcations, caimot be direcdy synthesized from amides and phosgene. Reactions of acid haUdes with cyanates have been suggested. However, the dominant commercial process utilizes the reaction of carboxamides with oxalyl chloride [79-37-8]. CycHc intermediates have been observed in these reactions which generally give a high yield of the desired products (86). 

Fatty acid chlorides are very reactive and can be used instead of conventional methods to faciUtate production of amides and esters. lmida2oles are effective recyclable catalysts for the reaction with phosgene (qv) (24). 

The reaction with disubstituted formamides and phosphorus oxychloride, called the Vilsmeier or the Vilsmeier-Haack reaction,is the most common method for the formylation of aromatic rings. However, it is applicable only to active substrates, such as amines and phenols. An intramolecular version is also known.Aromatic hydrocarbons and heterocycles can also be formylated, but only if they are much more active than benzene (e.g., azulenes, ferrocenes). Though A-phenyl-A-methyl-formamide is a common reagent, other arylalkyl amides and dialkyl amides are also used. Phosgene (COCI2) has been used in place of POCI3. The reaction has also been carried out with other amides to give ketones (actually an example of 11-14),... 

Carbachol Carbachol, 2-carbamoyloxy-iV,iV,iV-trimethylethyl ammonium chloride (13.1.7), is made by reacting 2-chloroethanol with phosgene, which forms 2-chloroethyl chloroformate (13.1.5). Upon reaction with ammonia, it turns into the corresponding amide (13.1.6), which is further reacted with an equimolar quantity of trimethylamine, giving carbachol (13.1.7) [9-13],... 

The use of activated anthranihc acid derivatives facUitates the preparation of the amides in those cases where the amines are either umeactive or difficult to obtain. Thus, reaction of (87-1) with phosgene gives the reactive the isatoic anhydride (89-1). Condensation of that with ortho-toluidine leads to the acylation product (89-2) formed with a simultaneous loss of carbon dioxide. This is then converted to the quinazolone (89-3) by heating with acetic anhydride. Reaction with sodium borohydride in the presence of aluminum chloride selectively reduces the double bond to yield the diuretic agent metolazone (89-4) [99]. 

When (253) reacts with phosgene the 1-acyl chloride product (254) can react with amines to give amides (79LA1756X while in a further transfer reaction with ketones the compounds (255) and (256) are produced (Scheme 146) (80H(14)97). Acylation of aromatic hydrocarbons using 1-acylimidazoles in the presence of trifluoracetic acid gives high yields provided that the aryl compounds are electron rich, e.g. p-dimethoxybenzene, thiophene, anisole <80BCJ1638). 

In the reactions with N-substituded amides, phosgene generaiiy acts as a chiorinating agent yo give Viismeier salts (see volume 2). As in the case of primary amides, the use of N-silyi amides is often required to observe N-acyia-tion in reasonable yields. 

Phosgenation of a-hydroxy acids affords cyclic mixed carboxylic-carbonic anhydrides which can be used as activated form of acid function in reaction with amines to afford amides as illustrated by the example given in scheme 182 (Ref. 235). 

A practically useful method for synthesis of selenoesters has been developed by Barton et al. A wide range of aliphatic and aromatic selenoesters have been synthesized from the appropriate N -disuh-stituted imidoyl chlorides (58) using sodium hydrogen selenide to introduce seleniumJ Imidoyl chlorides (58) can be obtained by the reaction of amides with phosgene. Representative results are shown in Scheme 17 (formulae 59-61). 

Phosgene, as well as the easier to handle diphosgene (chloroformic acid trichloromethyl ester) or triphosgene (carbonic acid bis(trichloromethyl) ester) transform primary, secondary and tertiary amides and thioamides to chloromethyleneiminium chlorides (25 equation 15), whereby the reaction with thioamides is of broader scope and proceeds with fewer side reactions. The amide chlorides derived from primary and secondary amides can lose HCl, giving nitriles or imidoyl halides, respectively. /V-Sub-stituted formamides can be converted to isonitriles via amide halides. ... 

Phosgene reacts, sometimes violently, with a large number of common inorganic (Chapter 9) and organic (Chapter 10) substances. Hazardous reactions with lithium, sodium, potassium, aluminium, lithium amide, hexa-2,4-diyn-l, 6-diol, propan-2-ol, and hexafluoropropene have been mentioned specifically [1787]. Mixtures of potassium and phosgene are reported to explode when subjected to shock [1913a]. In addition, phosgene... 

By-products, including urea, are generated by reaction of the generated ammonia with unreacted phosgene. In contrast, gaseous phosgene reacts with solid sodium amide at 250 C to form sodium cyanamide [1605] ... 

A further application of the metal-template effect in the ortho-regioselective acylation of phenols is represented by the direct synthesis of salicyloyl chloride and derivatives by the reaction of bromomagnesium phenolates 4 with phosgene. The reaction affords the unstable salicyloyl chloride-magnesium complexes 5 by a pathway similar to the mechanism depicted in Scheme 5.2. These intermediates can be in situ converted into the corresponding acids 6 (Scheme 5.3), esters, amides, or ketones by reaction with suitable reagents. 

---