Aldehydes cyanohydrin formation

Cyanohydrin formation is reversible and the position of equilibrium depends on the steric and electronic factors governing nucleophilic addition to carbonyl groups described m the preceding section Aldehydes and unhindered ketones give good yields of cyanohydrins... 

The reaction is used for the chain extension of aldoses in the synthesis of new or unusual sugars In this case the starting material l arabinose is an abundant natural product and possesses the correct configurations at its three chirality centers for elaboration to the relatively rare l enantiomers of glucose and mannose After cyanohydrin formation the cyano groups are converted to aldehyde functions by hydrogenation m aqueous solution Under these conditions —C=N is reduced to —CH=NH and hydrolyzes rapidly to —CH=0 Use of a poisoned palladium on barium sulfate catalyst prevents further reduction to the alditols... 

Cyanohydrin formation (Section 17.7) Hydrogen cyanide adds to the carbonyl group of aldehydes and ketones. 

Aldehydes and unhindered ketones undergo a nucleophilic addition reaction with HCN to yield cyanohydrins, RCH(OH)C=N. Studies carried out in the early 1900s by Arthur Eapworth showed that cyanohydrin formation is reversible and base-catalyzed. Reaction occurs slowly when pure HCN is used but rapidly when a small amount of base is added to generate the nucleophilic cyanide ion, CN. Alternatively, a small amount of KCN can be added to HCN to catalyze the reaction. Addition of CN- takes place by a typical nucleophilic addition pathway, yielding a tetrahedral intermediate that is protonated by HCN to give cyanohydrin product plus regenerated CN-. 

Attack by eCN is slow (rate-limiting), while proton transfer from HCN or a protic solvent, e.g. HzO, is rapid. The effect of the structure of the carbonyl compound on the position of equilibrium in cyanohydrin formation has already been referred to (p. 206) it is a preparative proposition with aldehydes, and with simple aliphatic and cyclic ketones, but is poor for ArCOR, and does not take place at all with ArCOAr. With ArCHO the benzoin reaction (p. 231) may compete with cyanohydrin formation with C=C—C=0, 1,4-addition may compete (cf. p. 200). 

This reaction of aromatic aldehydes, ArCHO, resembles the Cannizzaro reaction in that the initial attack [rapid and reversible—step (1)] is by an anion—this time eCN—on the carbonyl carbon atom of one molecule, the donor (125) but instead of hydride transfer (cf. Cannizzaro, p. 216) it is now carbanion addition by (127) to the carbonyl carbon atom of the second molecule of ArCHO, the acceptor (128), that occurs. This, in common with cyanohydrin formation (p. 212) was one of the earliest reactions to have its pathway established— correctly —in 1903. The rate law commonly observed is, as might be expected,... 

The first report on the reaction of D-pseudoephedrine 66 with phosphoryl chloride appeared as early as 1962 [49], More recently it was found that this condensation gave 2-chloro-l,3,2-oxazaphospholidine 2-oxides 67 as a single diastereomer which was subsequently esterified with racemic aldehyde cyanohydrins 68 without racemization at the phosphorus atom. The prepared diastereomeric esters 69 were used as substrates for the asymmetric synthesis of optically active cyanohydrins 72, which involves the intermediate formation of the tertiary esters 70, as shown in Scheme 22 [50],... 

Still another reaction of these aldehydic structures (formed by periodate oxidation), cyanohydrin formation, has been investigated.223... 

The reaction is reversible, and cyanohydrin formation is more favoinable with aldehydes than with ketones, as with other addition reactions. The reverse reaction is easily effected by treating a cyanohydrin with aqueous base, since cyanide is a reasonable leaving group (see Section 6.1.4). 

Stereoselective addition to aldehydes is another powerful tool in organic chemistry. Two very specihc types of this reaction include allylation of aldehydes and cyanohydrin formation. These are both reactions that can beneht from the use of chiral bis(oxazoline) ligands.Two examples are summarized in Figure 9.53. 

Usually the products of Cj-elongation are intermediates, rather than the target amino sugars. The elongation can be repeated iteratively [20]. Cyanohydrin formation belongs to the most typical C,-elongation processes. Addition of trimethylsilyl cyanide to a-amino aldehydes of type 1 in the presence of Lewis acid yielded a mixture of diastereoisomers 2 and 3 [21] (Scheme 3). 

Several carbonyl additions have characteristics similar to those of cyanohydrin formation. A typical example is the addition of sodium hydrogen sulfite, which proceeds readily with good conversion in aqueous solution with most aldehydes, methyl ketones, and unhindered cyclic ketones to form a carbon-sulfur bond. No catalyst is required because sulfite is an efficient nucleophilic agent. The addition step evidently involves the sulfite ion—not hydrogen sulfite ion ... 

Cyanohydrin formation is reversible, and the equilibrium constant may or may not favor the cyanohydrin. These equilibrium constants follow the general reactivity trend of ketones and aldehydes ... 

Formaldehyde reacts quickly and quantitatively with HCN. Most other aldehydes have equilibrium constants that favor cyanohydrin formation. Reactions of HCN with ketones have equilibrium constants that may favor either the ketones or the cyanohydrins, depending on the structure. Ketones that are hindered by large alkyl groups react slowly with HCN and give poor yields of cyanohydrins. 

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