Ketenes cyano

While the steric explanation is consistent with the observed selectivity, it nonetheless presents an incomplete explanation, as alkylation of 2-methyl-4-cyano-l,3-dioxane 17 also proceeded with very high syn-selectivity [11] (Eq. 5). The selective equatorial alkylation can be rationalized as an anfz-anomeric effect that disfavors axial alkylation of the ketene iminate through filled-shell repulsion. Simple lithiated nitriles are known to exist as ketene iminates, but it would be easy to rationalize the preference for equatorial alkylation by considering the relative stability of hypothetical equatorial and axial alkyllithium reagents, vide infra. Preferential equatorial alkylation was also observed by Beau... 

Fig. 37 Addition of phenols, 2-cyano-pyrrol, or hydrazoic acid to ketenes...

The method was efficiently extended to N,S-acetals by reacting 85.3, 85.6-85.9 with various N,S-acetals 17 to afford the corresponding 3-cyano-4-aminopyridines 99 (8 examples) <91S889>. Cyclohexanone ketene N,S-acetal 17.11 reacted with p-lithioamino crotononitrile 85.3 to afford the corresponding tetrahydroisoquinoline 100. 

Macrocyclic 2-pyrones (113) and (114) are prepared from enamine (115) and ketene (75HCA2409). Reduction of cyano ketone (116) with LAH affords an amino ketone which spontaneously cyclizes to generate a tetrahydropyridine (117) dehydrogenation by palladium on charcoal produces the aromatized phane (118) (71TL671). 

Dichloroketene acts as a donor toward aromatic aldehyde [165], but chlorocyano-ketene behaves as an acceptor, as shown by the reactivity profile with a series of substituted benzaldehydes [97]. It must be remembered that chloro and cyano groups belong to different polarity categories, and although the fundamental donor/acceptor characters of the ketene unit do not change, the higher electrophilidty of the cyano-ketene reflects the acceptor influence by the cyano function. 

Considerable use has also been made of allyl carbonates as substrates for the allylation of Pd enolates.9 The reaction of Pd° complexes with allyl enol carbonates119,120 proceeds by initial oxidative addition into the allylic C—O bond of the carbonate followed by decarboxylation, yielding an allylpalladium enolate, which subsequently produces Pd° and the allylated ketone (equation 22). In like fashion, except now in an intermolecular sense, allyl carbonates have been found to allylate enol silyl ethers (equation 23),121 enol acetates (with MeOSnBu3 as cocatalyst) (equation 24),122 ketene silyl acetals (equation 25)123 and anions a to nitro, cyano, sulfonyl and keto groups.115,124 In these cases, the alkoxy moiety liberated from the carbonate on decarboxylation serves as the key reagent in generating the Pd enolate. 

The thermal reaction of 6-amino-4-oxopyrano[3,4-d][l,2,3]thiadiazoles (32) leads to 6-hydroxy-4-oxo-[l,2,3]thiadiazolo[4,5-c]pyridines (33) and 2-cyano-2-(l,2,3-thiadia-zol-5-yl)acetamide (34).58 Formation of (33), a Dimroth-type rearrangement, proceeds by thermal opening of the pyrane ring, followed by the simultaneous rotational isomerization of the ketene intermediate and its recyclization on to the amido group to form the pyridin-2-one cycle. 

Intermolecular addition of carbon nucleophiles to the ri2-pyrrolium complexes has shown limited success because of the decreased reactivity of the iminium moiety coupled with the acidity (pKa 18-20) of the ammine ligands on the osmium, the latter of which prohibits the use of robust nucleophiles. Addition of cyanide ion to the l-methyl-2//-pyr-rolium complex 32 occurs to give the 2-cyano-substituted 3-pyrroline complex 75 as one diastereomer (Figure 15). In contrast, the 1-methyl-3//-pyrrolium species 28, which possesses an acidic C-3-proton in an anti orientation, results in a significant (-30%) amount of deprotonation in addition to the 2-pyrroline complex 78 under the same reaction conditions. Uncharacteristically, 78 is isolated as a 3 2 ratio of isomers, presumably via epimerization at C-2.17 Other potential nucleophiles such as the conjugate base of malononitrile, potassium acetoacetate, and the silyl ketene acetal 2-methoxy-l-methyl-2-(trimethylsiloxy)-l-propene either do not react or result in deprotonation under ambient conditions. 

The photolytic Wolff ring contraction of diazopyridones 247 leads to pyrrole-2-carboxylic acids 250 via carbene 248 and ketene 249 intermediates <1976S754>. The thermolysis of 2-azidopyridine A-oxides 251 affords A-hydroxy-2-cyano-pyrroles 252 (Scheme 137) <1973JOC173> (see also Section 3.4.3.11). 

The reaction of amines and ketene acetals was used as a main synthetic approach to 1,1-enediamines in earlier years72. Both simple and conjugated 1,1-enediamines can be obtained by this route. Displacement reaction of ketene acetal 34 with two equivalents of piperidine furnishes 1,1-dipiperidinoethene (35) in 62% yield (equation 9)73. Primary amines and ammonia react with 34 to give amidine derivatives. Cyano-74 and trifluor-oacetyl-substituted enediamines75 have been synthesized from the corresponding ketene acetals in good to excellent yields (e.g. equation 10). 

Ketazines, 395 Ketene, 76,275 Ketene thioaoetals, 284,413 Ketimines, 345 d-Keto acids, 538 a-Ketocarbenes, 100 7-Ketocholesteryl acetate, 51 5-Keto-6-cyano-5,6-secosteroids, 277... 

A minor product of the reaction of 1-methylcyclopropene with tert-butyl(cyano)ketene was a furan 1. ... 

Reaction of 3,3-dimethylcyclopropene with /crt-butyl(cyano)ketene gave a bicyclobutanone 1 by a formal [2-1-2] cycloaddition, and also a 2 1 product 2. ... 

Lactones, synthesis from cyano ketenes 81CSR289. 

Construction of the suitably substituted geranic acid for making the furan ring has been effected too. For example, Poulter et al. have prepared the substituted geranate 865 by reaction of 4-methyl-3-pentenylcopper with the acetylenic ester 866. The ester 865 then underwent cyclization in the presence of acid to the lactone 867, related to scobinolide (161), and the action of acid on the lactol produced from 867 with diisobutylaluminum hydride gave perillene (849). The lactone 867 has also been prepared by a slightly different method the C9 alcohol 868 was made (in poor yield) from isobutenol and prenyl chloride with butyllithium. The extra carbon atom was introduced by the action of sodium cyanide on the epoxide of 868, and hydrolysis of the cyano group followed by dehydration yielded the lactone 867. The dimethylthioacetal of 867 has been used to synthesize perillene (849). This thioacetal was made from the suitably substituted ketene thioacetal 869 and dimethylsulfonium methylide. Thus the ketene thioacetal 870 (readily prepared from acetone, carbon disulfide, and sodium amylate, followed by methylation °) can be prenylated with lithium... 

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