Carbonyl compounds reaction with cyanide

At the beginning of the chapter, we mentioned the fact that carbonyl compounds react with cyanide. We are now going to deduce a mechanism. This is the reaction ... 

Officially, the history of MCRs dates back to the year 1850, with the introduction of the Strecker reaction (S-3CR) describing the formation of a-aminocyanides from ammonia, carbonyl compounds, and hydrogen cyanide [4]. In 1882, the reaction progressed to the Hantzsch synthesis (H-4CR) of 1,4-dihydropyridines by the reaction of amines, aldehydes, and 1,3-dicarbonyl compounds [5], Some 25 years later, in 1917, Robinson achieved the total synthesis of the alkaloid tropinone by using a three-component strategy based on Mannich-type reactions (M-3CR) [6]. In fact, this was the earliest application of MCRs in natural product synthesis [7]. 

Exercise 16-10 One possible way of carrying out the cyanohydrin reaction would be to dispense with hydrogen cyanide and just use the carbonyl compound and sodium cyanide. Would the equilibrium constant for cyanohydrin formation be more... 

Cyanohydrins are usually prepared from carbonyl compounds and a cyanide source. Initially performed with volatile and very toxic hydrogen cyanide, the reaction is now carried out with safer cyanide agents, such as acetone cyanohydrin, acyl cyanides, cyanoformates or the most used trimethylsilyl cyanide. In terms of atom economy, this reaction is 100% atom efficient and is widely used despite the toxicity of the reagents. The asymmetric reaction can now be efficiently catalysed by a variety of chiral Lewis acids, and a recent review presents in detail the work realised in this field, with a large description of titanium-based catal)dic systems. 

Some imine-forming reactions are shown in Figure 14.30—all of these were part of longer synthetic sequences. Imines undergo many of the same types of addition reactions as aldehydes and ketones. A particularly useful example of this is their reaction with cyanide ion, the Strecker reaction (Figure 14.31). When a carbonyl compound is treated with ammonia and sodium or KCN, the ammonia adds to the carbonyl to give an unstable imine. This is attacked by cyanide to give the a-aminocyanide. Since the cyanide can be hydrolyzed to a carboxylic acid, this constitutes a simple amino acid synthesis. 

Some organosilicon compounds undergo transmetallation. The allylic cyanide 461 was prepared by the reaction of an allylic carbonate with trimethylsi-lyl cyanide[298]. The oriho esters and acetals of the o. d-unsaturated carbonyl compounds 462 undergo cyanation with trimefhylsilyl cyanide[95]. 

Production of cyanohydrins is accompHshed through the base-cataly2ed combination of hydrogen cyanide and the carbonyl compound in a solvent, usually the cyanohydrin itself (17). The reaction is carried out at high dilution of the feeds, at 10—15°C, and pH 6.5—7.5. The product is continuously removed from the reaction 2one, cooled to push the equilibrium toward cyanohydrin formation, and then stabili2ed with mineral acid. Purification is usually effected by distillation. 

In summary, the Bucherer-Bergs reaction converts aldehydes or ketones to the corresponding hydantoins. It is often carried out by treating the carbonyl compounds with potassium cyanide and ammonium carbonate in 50% aqueous ethanol. The resulting hydantoins, often of pharmacological importance, may also serve as the intermediates for amino acid synthesis. 

The reduction of carbonyl compounds by reaction with hydride reagents (H -) and the Grignard addition by reaction with organomagnesium halides (R - +MgBr) are examples of nucleophilic carbonyl addition reactions. What analogous product do you think might result from reaction of cyanide ion with a ketone ... 

Nitriles are similar in some respects to carboxylic acids and are prepared either by SN2 reaction of an alkyl halide with cyanide ion or by dehydration of an amide. Nitriles undergo nucleophilic addition to the polar C=N bond in the same way that carbonyl compounds do. The most important reactions of nitriles are their hydrolysis to carboxylic acids, reduction to primary amines, and reaction with organometallic reagents to yield ketones. 

Naturally occurring compounds called cyanogenic glycosides, such as lotau-stralin, release hydrogen cyanide, HCN, when treated with aqueous acid. The reaction occurs by hydrolysis of the acetal linkage to form a cyanohydrin, which then expels HCN and gives a carbonyl compound-fa) Show the mechanism of the acetal hydrolysis and the structure of the cyanohydrin that results. 

Acyloins (a-hydroxy ketones) are formed enzymatically by a mechanism similar to the classical benzoin condensation. The enzymes that can catalyze reactions of this type arc thiamine dependent. In this sense, the cofactor thiamine pyrophosphate may be regarded as a natural- equivalent of the cyanide catalyst needed for the umpolung step in benzoin condensations. Thus, a suitable carbonyl compound (a -synthon) reacts with thiamine pyrophosphate to form an enzyme-substrate complex that subsequently cleaves to the corresponding a-carbanion (d1-synthon). The latter adds to a carbonyl group resulting in an a-hydroxy ketone after elimination of thiamine pyrophosphate. Stereoselectivity of the addition step (i.e., addition to the Stand Re-face of the carbonyl group, respectively) is achieved by adjustment of a preferred active center conformation. A detailed discussion of the mechanisms involved in thiamine-dependent enzymes, as well as a comparison of the structural similarities, is found in references 1 -4. 

Racemic hydantoins result from the reaction of carbonyl compounds with potassium cyanide and ammonium carbonate or the reaction of the corresponding cyanohydrins with ammonium carbonate (Bucherer-Bergs reaction). Hydantoins racemize readily under basic conditions or in the presence of hydantoin racemase, thus allowing DKR (Figure 6.43). Hydantoinases (EC 3.5.2.2), either isolated enzymes or whole microorganisms, catalyze the hydrolysis of five-substituted... 

Addition of cyanide ion to a carbonyl compound leads to a cyanohydrin, a process with many applications including the synthesis of amino adds via an aminonitrile. The dired reaction between an aldehyde, KCN and NH4CI in acetonitrile leads to a mixture... 

Formation of hydantoins from carbonyl compounds with potassium cyanide (KCN) and ammonium carbonate [(NH4)2C03] or from cyanohydrins and ammonium carbonate. It belongs to the category of multiple component reaction (MCR). 

Not only cyanide but also an isocyanide behaves as a nucleophile to attack a carbonyl compound or an imine that is prepared in situ from an carbonyl compound. " In these reactions, an isocyanide is a synthetic equivalent to an aminocarbonyl anion. Asymmetric version of this reaction appeared in 2003. Using a combination of Lewis acid SiCU and a Lewis base chiral bisphosphora-mide, the corresponding a-hydroxyamide is obtained in 96% yield with >98% ee (Scheme 4.23). 

The mechanism for replacement of a methoxyl group by cyanide in these reactions follows Scheme 6.7. The radical-cation reacts with cyanide ion at the point of highest positive charge density. Oxidation of the radical so formed to the carbon-ium ion is followed by elimination of proton and formaldehyde [79]. The elimination step is analogous to the conversion of cyanhydrins to the carbonyl compound and cyanide ion in basic solution. 

The apparently quite broad structural requirements for anticonvulsant activity, noted earlier in this chapter, extend to yet another class of five-membered heterocycles that include an imide function. Imidazo-2,4-diones, better known as hydan-toins, have comprised some of the most widely used drugs for treating severe motor and psychomotor epileptic seizures. The general reaction used to prepare this heterocyclic system involves the treatment of a carbonyl compound with ammonium carbonate and potassium cyanide. The first step in the complex sequence can be visualized as the addition of the elements of ammonia and hydrogen cyanide to give an a-aminonitrile (88-2). Addition of ammonia to the cyano group would then lead to an amidine (88-3). Carbon dioxide or carbonate ion present in the reaction... 

Amino-1 //-1,2,4-triazole and its derivatives are frequently used as precursors for this ring via their reaction with suitable carbonyl compounds. The 5-amino-l,2,4-triazoles (27), prepared from calcium cyanide by hydrolysis to cyanamide followed by condensation with hydrazine (92MI4), reacted with the appropriate acetophenone in presence of ZnCl2 to give the... 

URECH CYANOHYDRIN METHOD. Cyanohydrin formation by addition of alkali cyanide to the carbonyl group in the presence of acetic acid (Urech) or by reaction of the carbonyl compound with anhydrous hydrogen cyanide in the presence of basic catalyst (Ultee). 

The second step regenerates the cyanide ion. Each step of the reaction is reversible but, with aldehydes and most nonhindered ketones, formation of the cyanohydrin is reasonably favorable. In practical syntheses of cyanohydrins, it is convenient to add a strong acid to a mixture of sodium cyanide and the carbonyl compound, so that hydrogen cyanide is generated in situ. The amount of acid added should be insufficient to consume all the cyanide ion, therefore sufficiently alkaline conditions are maintained for rapid addition. 

Reaction of cyanide ion with an alkyl halide is often the most convenient route to a nitrile, but in those cases where the corresponding aldehyde or ketone is more readily available than the alkyl halide, the following procedure is very convenient. The carbonyl compound is first converted into its 2,4,6-triisopropyl-benzenesulphonyl hydrazone (1) (Expt 6.42 gives the method for the preparation of the reagent, TBSH), which without isolation is then reacted with potassium cyanide under gentle reflux.169... 

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