Cyanohydrins, ketone synthesis

Silylated cyanohydrins have also been prepared via silylation of cyanohydrins themselves and by the addition of hydrogen cyanide to silyl enol ethers. Silylated cyanohydrins have proved to be quite useful in a variety of synthetic transformations, including the regiospecific protection of p-quinones, as intermediates in an efficient synthesis of a-aminomethyl alcohols, and for the preparation of ketone cyanohydrins themselves.The silylated cyanohydrins of heteroaromatic aldehydes have found extensive use as... 

Kragl and coworkers investigated using organic-solvent-free systems to overcome the thermodynamic limitations in the synthesis of optically active ketone cyanohydrins. With organic-solvent-free systems under optimized reaction conditions, conversions up to 78% with > 99.0 enantiomeric excess (ee) (S) were obtained. Finally, 5 mL of (S)-acetophenone cyanohydrin with an ee of 98.5% was synthesized using MeHNL [52]. 

Effenberger, F., Hoersch, B., Weingart, F. et al. (1991) Enzyme-catalyzed synthesis or (/ )-ketone-cyanohydrins and their hydrolysis to (R)-a-hydroxy-a-methyl-carboxylic acids. Tetrahedron Letters, 32, 2605-2608. 

Biihler, H., Bayer, A. and Effenberger, F. (2000) Enzyme-catalyzed reactions, part 39. A convenient synthesis of optically active 5,5-disubstituted 4-amino- and 4-hydroxy-2(5f/)-furanones from (5)-ketone cyanohydrins. Chemistry - A European Journal, 6, 2564—2571. 

The production of optically active cyanohydrins, with nitrile and alcohol functional groups that can each be readily derivatized, is an increasingly significant organic synthesis method. Hydroxynitrile lyase (HNL) enzymes have been shown to be very effective biocatalysts for the formation of these compounds from a variety of aldehyde and aliphatic ketone starting materials.Recent work has also expanded the application of HNLs to the asymmetric production of cyanohydrins from aromatic ketones. In particular, commercially available preparations of these enzymes have been utilized for high ee (5)-cyanohydrin synthesis from phenylacetones with a variety of different aromatic substitutions (Figure 8.1). 

We began our synthesis by finding the optimum reaction conditions for the catalytic asymmetric cyanosilylation of ketone 28 (Table 1). Based on previous studies,30 the titanium complex of a D-glucose derived ligand (catalyst 32 or 33) generally gives (/ )-ketone cyanohydrins, which is required for a synthesis of natural fostriecin. 

The cyanohydrin synthesis of a-hydroxy acids is very often carried out without isolation or purification of the cyanohydrins. The various techniques for the preparation of the cyanohydrins are discussed elsewhere (method 390). Hydrolysis to the a-hydroxy acids is usually effected by heating with concentrated hydrochloric acid. Excellent directions are given for mandelic acid (52% over-all from benzaldehyde), a-methyl-a-hydroxybutyric acid (65% from methyl ethyl ketone), and eighteen dialkyl- and alkylphenyl-glycolic acids (60-80%). Sodium hydroxide solution is used in the preparation of /S-hydroxypropionic acid from the /S-hydroxy nitrile (80%). ... 

Similar to the cyanohydrin synthesis for hydroxy acids is the Strecker synthesis of amino acids. Aldehydes and ketones are converted to a-amino cyanides by ammonia and hydrogen cyanide or by aqueous ammonium chloride and sodium cyanide solutions. Amino cyanides may also be obtained by the action of gaseous ammonia on cyanohydrins (cf. method 391). The preparation of DL-alanine (60%) is typical. "... 

The addition of hydrogen cyanide to carbonyl compounds gives a-hydroxy cyanides (cyanohydrin synthesis). The reaction is reversible, and the extent of the cyanohydrin formation depends upon the structure of the Carbonyl compound. The equilibrium highly favors the formation of aliphatic and alicyclic cyanohydrins however, aryl alkyl ketones react to a lesser extent, and diaryl ketones, not at all. The reaction may be accomplished by mixing the carbonyl compound with liquid hydrogen cyanide in the presence of a basic catalyst. The equilibrium... 

Cyano halides, see Halo cyanides Cyanohydrins, see Hydroxy cyanides Cyanohydrin synthesis, 414, 604 Cyano iniides, preparation, 434 Cyano ketones, see Keto cyanides a-Cyano lactones, preparation, 534 Cyclodehydration of ketones and alcohols, 15, 843... 

The alkylation of protected cyanohydrin anions constitutes an excellent method for ketone synthesis. Generally the anions are generated from aliphatic or aromatic aldehyde protected cyanohyd with LDA under nitrogen at -78 C. The addition of an alkyl halide produces the protected ketone cyanohydrin. The carbonyl group is then liberated by successive treatment with dilute acid and dilute aqueous base. This method is applicable for the synthesis of buflomedil. ... 

Table 3. Synthesis of (R)-ketone cyanohydrins by Prunus amygdalus oxynitrilase catalysed addition of HCN to A methyl ketones (RCOCH3) and B ethyl ketones (RCOCHjCH,)...

A modification of the cyanohydrin synthesis is provided by Strecker s amino acid synthesis, in which an <%-amino nitrile is obtained by the action of hydrogen cyanide and ammonia on an aldehyde or ketone ... 

F. Effenberger, S. Held, (R)-Oxynitrilase catalyzed synthesis of (R)-ketone cyanohydrins. Tetrahedron Asymmetry 6 (1995) 2945-2952. 

The most general methods for the syntheses of 1,2-difunctional molecules are based on the oxidation of carbon-carbon multiple bonds (p. 117) and the opening of oxiranes by hetero atoms (p. 123fl.). There exist, however, also a few useful reactions in which an a - and a d -synthon or two r -synthons are combined. The classical polar reaction is the addition of cyanide anion to carbonyl groups, which leads to a-hydroxynitriles (cyanohydrins). It is used, for example, in Strecker s synthesis of amino acids and in the homologization of monosaccharides. The ff-hydroxy group of a nitrile can be easily substituted by various nucleophiles, the nitrile can be solvolyzed or reduced. Therefore a large variety of terminal difunctional molecules with one additional carbon atom can be made. Equally versatile are a-methylsulfinyl ketones (H.G. Hauthal, 1971 T. Durst, 1979 O. DeLucchi, 1991), which are available from acid chlorides or esters and the dimsyl anion. Carbanions of these compounds can also be used for the synthesis of 1,4-dicarbonyl compounds (p. 65f.). 

Out first example is 2-hydroxy-2-methyl-3-octanone. 3-Octanone can be purchased, but it would be difficult to differentiate the two activated methylene groups in alkylation and oxidation reactions. Usual syntheses of acyloins are based upon addition of terminal alkynes to ketones (disconnection 1 see p. 52). For syntheses of unsymmetrical 1,2-difunctional compounds it is often advisable to look also for reactive starting materials, which do already contain the right substitution pattern. In the present case it turns out that 3-hydroxy-3-methyl-2-butanone is an inexpensive commercial product. This molecule dictates disconnection 3. Another practical synthesis starts with acetone cyanohydrin and pentylmagnesium bromide (disconnection 2). Many 1,2-difunctional compounds are accessible via oxidation of C—C multiple bonds. In this case the target molecule may be obtained by simple permanganate oxidation of 2-methyl-2-octene, which may be synthesized by Wittig reaction (disconnection 1). 

Historically these compounds have been made in two-step processes. Eor smaller volumes, reaction of an appropriate ketone or aldehyde with a cyanide salt followed by treatment with an ammonium salt proves satisfactory (Strecker synthesis). Eor larger volumes, treatment of the ketone or aldehyde with HCN to produce a cyanohydrin, followed by treatment with ammonia has been practiced. However, in 1990, DuPont began practicing a new one-step... 

Hydroxyl Group. The OH group of cyanohydrins is subject to displacement with other electronegative groups. Cyanohydrins react with ammonia to yield amino nitriles. This is a step in the Strecker synthesis of amino acids. A one-step synthesis of a-amino acids involves treatment of cyanohydrins with ammonia and ammonium carbonate under pressure. Thus acetone cyanohydrin, when heated at 160°C with ammonia and ammonium carbonate for 6 h, gives a-aminoisobutyric acid [62-57-7] in 86% yield (7). Primary and secondary amines can also be used to displace the hydroxyl group to obtain A/-substituted and Ai,A/-disubstituted a-amino nitriles. The Strecker synthesis can also be appHed to aromatic ketones. Similarly, hydrazine reacts with two molecules of cyanohydrin to give the disubstituted hydrazine. 

In a German patent issued in 1929, Bergs described a synthesis of some 5-substituted hydantoins by treatment of aldehydes or ketones (1) with potassium cyanide, ammonium carbonate, and carbon dioxide under several atmospheres of pressure at 80°C. In 1934, Bucherer et al. isolated a hydantoin derivative as a by-product in their preparation of cyanohydrin from cyclohexanone. They subsequently discovered that hydantoins could also be formed from the reaction of cyanohydrins (e.g. 3) and ammonium carbonate at room temperature or 60-70°C either in water or in benzene. The use of carbon dioxide under pressure was not necessary for the reaction to take place. Bucherer and Lieb later found that the reaction proceeded in 50% aqueous ethanol in excellent yields for ketones and good yields for aldehydes. ... 

Stork s elegant use of a protected cyanohydrin function in the synthesis of PGF2a (2) is also noteworthy. The electron-withdrawing cyano substituent in intermediate 21 (Scheme 7) confers nucleophilic potential to C-9 and permits the construction of the saturated cyclopentane nucleus of PGF2a (2) through intramolecular alkylation. In addition, the C-9 cyanohydrin function contained within 40 is stable under the acidic conditions used to accomplish the conversion of 39 to 40 (see Scheme 7), and it thus provides suitable protection for an otherwise labile /J-hydroxy ketone. 

Today, the most promising synthesis of optically active cyanohydrins, especially with respect to the enantioselectivity of the reaction, is the enzyme-catalyzed addition of hydrogen cyanide to aldehydes and ketones, respectively. 

Stork first demonstrated the utility of protected cyanohydrins as acyl anion equivalents in 1971 [2]. The acetal-protected cyanohydrin 8 was transformed into the corresponding anion with LDA in THF/HMPA, which was then alkylated with a range of alkyl halides, including secondary bromides (Scheme 2). A mild acidic hydrolysis yielded a cyanohydrin, which provided the ketone after treatment with base. The Stork cyanohydrin alkylation and its variants have become important methods in natural product synthesis [3,4]. 

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