Alkyl isocyanates reaction with

Chloroperoxidase catalysis by, 58, 302 in chlorination of pyrazoles, 57, 337 Chlorophyll, thioaldehyde synthetic intermediate to, 55, 3 Chlorosulfonyl isocyanate, reaction with 2-arylhydrazono-3-oxobutanoate, 59, 148 Chromatography, of [l,2,4]triazolo[l,5-a]-pyrimidines, 57, 106 Chrom-3-enes, see 2//-l-Benzopyrans Chromium tricarbonyl complexes of 3,5-diphenyl-l-(alkyl- or oxido-)-thiabenzenes, 59, 206, 227 indoles, lithiation of, 56, 181, 184 of pyridine, 58, 160 pyridines, lithiation of, 56, 230, 239 of 2f/-thiopyrans, 59, 227 Chromones, see l-Benzopyran-4-ones Cinnamonitrile, a-cyano-, condensations with thio-, seleno-amides, 59, 184, 186 Cinnoline, nitration, MO calculation, 59, 302... 

Treating methyl 4-methylaminobenzoate with AT-chlorosulfonyl isocyanate in the presence of AICI3 leads to the benzo-l-thia-2,4-diazine 1,1-dioxide adduct, which after N-alkylation and reaction with benzylic amines affords the... 

The insertion reaction of isocyanates into C-Cl bonds requires Lewis acids or carbon as a catalyst. For example, alkyl isocyanates react with phosgene at 150 °C, in the presence of carbon, to give the insertion product 256. A better synthesis of the insertion product is the reaction of the sulfur heterocycle 257 with chlorine... 

Reaction of 2-aminothiazoles with alkyl isocyanates yields 2-thiazolylureas (256) (Scheme 153) (479-483). This reaction is general and works with acyl isocyanates (484. 485). These heterocyclic ureas are also prepared by the reaction of H2O on 2-thia2olylcyanamide (486) or by action of HjOj on the corresponding thiourea (303, 481). 

Reaction of 2-imino-3-alkyl-4-thiazolines with alkyl isocyanates gives the ureas (382), which when nitrated on C-5 give the schistosomicide class of compounds (383) (Scheme 219), When nitration takes place on the ring... 

Another common process iavolves reaction with C=C or C=N species having adjacent CH2 or CH groups. Initial attack of the isocyanate is on the electron-rich center of the double bond with subsequent migration and iasertion of the CONR group iato the CH bond. Suitable reagents iaclude A/-alkylated acetamidines, 1-methyl dihydroisoquiaoline, and 2-methyl-2-oxa2oline [1120-64-5] (35). 

Commercially important arenesulfonyl isocyanates are not directly accessible from the corresponding sulfonamides via phosgenation due to lack of reactivity or by-product formation at elevated temperatures. A convenient method for their preparation consists of the reaction of alkyl isocyanates with sulfonamides to produce mixed ureas which, upon phosgenation, yield a mixture of alkyl and arenesulfonyl isocyanates. The desired product can be obtained by simple distillation (16). Optionally, the oxalyl chloride route has been employed for the synthesis of arenesulfonyl isocyanate (87). 

Naphthalenesulfonic acid can be converted to l-naphthalenethiol/T25 -J6 - by reduction of the related sulfonyl chloride this product has some utihty as a dye intermediate, and is converted by reaction with alkyl isocyanates to 3 -naphthyl-A/-alkylthiocarbamates, which have pesticidal and herbicidal... 

Phosgene reacts with a multitude of nitrogen, oxygen, sulfur, and carbon centers. Reaction with primary alkyl and aryl amines yield carbamoyl chlorides which are readily dehydrohalogenated to isocyanates. Secondary amines also form carbamoyl chlorides. 

Methylarsine, trifluoromethylarsine, and bis(trifluoromethyl)arsine [371-74-4] C2HAsF, are gases at room temperature all other primary and secondary arsines are liquids or solids. These compounds are extremely sensitive to oxygen, and ia some cases are spontaneously inflammable ia air (45). They readily undergo addition reactions with alkenes (51), alkynes (52), aldehydes (qv) (53), ketones (qv) (54), isocyanates (55), and a2o compounds (56). They also react with diborane (43) and a variety of other Lewis acids. Alkyl haUdes react with primary and secondary arsiaes to yield quaternary arsenic compounds (57). 

Phenyl isocyanates are generally more reactive than alkyl isocyanates in their reactions with alcohols, but with CuCl catalysis even alkyl isocyanates will react readily with primary, secondary, or tertiary alcohols (45-95% yield). ... 

The Cunius degradation of acyl azides prepared either by treatment of acyl halides with sodium azide or trimethylsilyl azide [47] or by treatment of acyl hydrazides with nitrous acid [f J yields pnmarily alkyl isocyanates, which can be isolated when the reaction is earned out in aptotic solvents If alcohols are used as solvents, urethanes are formed Hydrolysis of the isocyanates and the urethanes yields primary amines. 

The reaction of the enamines of cyclic ketones with alkyl isocyanates, acyl isocyanates, phenyl isothiocyanates, and acyl isothiocyanates has also been reported 112). The products are the corresponding carboxamides. The products from the isothiocyanates have been utilized as intermediates in the preparation of various heterocyclic compounds 113). 

The synthesis of 5-aminothiazoles via the reaction of isocyanate derivatives with aminomalononitrile p-toluenesulfonate (AMNT) has been investigated. It was found that AMNT 12 reacted with alkyl and aryl isothiocyanates in l-methyl-2-pyrrolidine (NMP) to furnish 5-amino-2-(alkylamino)-4-cyanothiazoles (13a) and 5-amino-2-(arylamino)-4-cyanothiazoles (13b-c) in 44-81 % yields. " ... 

Cycloadditions of isocyanates and their derivatives with vinyiaziridines were first reported by Alper and coworkers. From their previous studies of cydoadditions to vinylepoxides or alkylaziridines, they investigated cydoadditions to vinyiaziridines and found that such reactions with isocyanates, carbodiimides, or isothiocyanates in the presence of catalytic amounts of Pd(OAc)2 (2 mol%) and PPh3 (10 mol%) at room temperature afforded five-membered ring products 249 in 34—97% yields (Scheme 2.61) [91]. When an aziridine 247 possessing an alkyl substituent at the... 

Scheme 18). Three reactions at OH-2 were investigated, namely carbamatations by reaction with isocyanates, etherifications by reaction with alkyl bromides, and substitution by an azide after intermediate triflate formation. 

Monocarbamoylation of diols is generally accomplished only with great difficulty. Reaction of the diol with an alkyl isocyanate is a possibility, but trimerization of the isocyanate frequently occurs [73]. The monocarbamic esters, which have PAF receptor antagonist activity, can be obtained however in acceptable yields via the phase-transfer catalysed in situ formation of the alkyl isocyanate from potassium isocyanate and an alkyl halide, and its subsequent reaction with the diol (see Scheme 3.8 for typical examples) [74], The diols tend to react more rapidly than do simple alcohols and m-diols are more effectively esterified that are /ra/rs-diols. Additionally, the longer the chain length between the hydroxyl centres, the less effective is the reaction. This has led to the reasonable hypothesis that a cyclic H-bonded intermediate between the two hydroxyl groups and the alkyl isocyanate are critical for the preferential and rapid formation of the carbamate. 

Alkyl and glycosyl isocyanates and isothiocyanates are produced in good yield under phase-transfer catalytic conditions using either conventional soluble catalysts or polymer-supported catalysts [32, 33]. Acyl isothiocyanates are obtained under similar conditions [34]. A-Aryl phosphoramidates are converted via their reaction with carbon disulphide under basic conditions into the corresponding aryl isothiocyanates, when the reaction is catalysed by tetra-n-butylammonium bromide [35]. 

A theoretical study of the reaction of water and methanol with HNCO has led to a prediction of a four-centred transition state for both reactions. The interactions of water and of alcohols with alkyl isocyanates have been the subject of both experimental and theoretical study. In the case of hydration, evidence for initial interaction of water and water clusters (n = 1-3) across the N=C bond of the alkyl isocyanate... 

Trialkylsilyl radicals add to alkyl isocyanate to form imidoyl radicals 56 (Reaction 5.38). Detailed EPR studies established intermediates 56 to be strongly bent at the carbon bearing the unpaired electron [76], The absolute rate constant for the reaction of Et3Si radical with ieri-butyl isocyanate was found to be 5.5 x 10 s at 27 °C [13], whereas the relative rate of the addition of MesSi radicals to alkyl isocyanates was found to decrease in the... 

An aza-Wittig reaction with carbonyl electrophiles, accessible from im-inophosphorane (177) and aldehydes, gives 5-alkyl- or 5-aryl-lf/-l,2,4-triazoles (Scheme 69) (85S304). The reaction of 177 with isocyanate generates two different products, both of which occur from primary adduct... 

Alkyl lV,lV-dinitramines (154) have been prepared from the reaction of the tetraalkylam-monium salts (155) of primary nitramines with nitryl fluoride in acetonitrile at subambient temperature. The same reaction with the primary nitramine or its alkali metal salts yields the corresponding nitrate ester. Treatment of the ammonium, potassium, or lithium salts of primary nitramines (156) with a solution of nitronium tetrafluoroborate in acetonitrile at subambient temperature yield alkyl iV,iV-dinitramines. ° The same reactions in ether or ester solvents enables the free nitramine to be used. The nitrolysis of A-alkylnitramides (157) and N,N-diacylamines with nitronium tetrafluoroborate in acetonitrile, and the nitration of aliphatic isocyanates with nitronium tetrafluoroborate and nitric acid in acetonitrile, also yield alkyl A,A-dinitramines (154). 

This reaction is typical for the synthesis of sulfonylureas it is mildly exothermic and proceeds smoothly in a variety of inert aprotic solvents. The product is usually obtained in very high yield, as a fine crystalline precipitate. The sulfonyl isocyanates are readily prepared from the substituted benzene sulfonamides by reaction with phosgene, Fig. 3, in the presence of an alkyl isocyanate, for example, butyl isocyanate in an inert solvent at 120 to 140°C according to the general procedure of H. Ulrich and A. A. R. Sayigh (Ref. 3). 

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