Acetone cyanohydrin synthesis

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). 

Until 1982, almost all methyl methacrylate produced woddwide was derived from the acetone cyanohydrin (C-3) process. In 1982, Nippon Shokubai Kagaku Kogyo Company introduced an isobutylene-based (C-4) process, which was quickly followed by Mitsubishi Rayon Company in 1983 (66). Japan Methacryhc Monomer Company, a joint venture of Nippon Shokubai and Sumitomo Chemical Company, introduced a C-4-based plant in 1984 (67). Isobutylene processes are less economically attractive in the United States where isobutylene finds use in the synthesis of methyl /i / butyl ether, a pollution-reducing gasoline additive. BASF began operation of an ethylene-based (C-2) plant in Ludwigshafen, Germany, in 1990, but favorable economics appear to be limited to conditions unique to that site. 

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. 

Cyanohydrin Synthesis. Another synthetically useful enzyme that catalyzes carbon—carbon bond formation is oxynitnlase (EC 4.1.2.10). This enzyme catalyzes the addition of cyanides to various aldehydes that may come either in the form of hydrogen cyanide or acetone cyanohydrin (152—158) (Fig. 7). The reaction constitutes a convenient route for the preparation of a-hydroxy acids and P-amino alcohols. Acetone cyanohydrin [75-86-5] can also be used as the cyanide carrier, and is considered to be superior since it does not involve hazardous gaseous HCN and also virtually eliminates the spontaneous nonenzymatic reaction. (R)-oxynitrilase accepts aromatic (97a,b), straight- (97c,e), and branched-chain aUphatic aldehydes, converting them to (R)-cyanohydrins in very good yields and high enantiomeric purity (Table 10). 

This synthesis of N-nitromorpholine is representative of a rather general reaction for the preparation of both primary and secondary nitramines.3 It represents the simplest process for obtaining both types of compounds. The reaction is unique in that a nitration is carried out under neutral or alkaline conditions. Acetone cyanohydrin nitrate may also be used for the nitration of many active methylene compounds.8... 

In 1992, Oda et al. reported a one-pot synthesis of optically active cyanohydrin acetates from aldehydes, which were converted to the corresponding racemic cyanohydrins through transhydrocyanation with acetone cyanohydrin, catalyzed by a a strongly basic anion-exchange resin [46]. The racemic cyanohydrins were acetylated by a lipase from P. cepacia (Amano) with isopropenyl acetate as the acyl donor. The reversible nature of the base-catalyzed transhydrocyanation enabled continuous racemization of the unreacted cyanohydrins, thereby effecting a total conversion (Figure 4.21). 

Since the key thermal rearrangement was optimized, we turned our attention to earlier steps. The synthesis of amidoxime 7 was optimized from acetone cyanohydrin 4 (Scheme 6.6). The original Strecker reaction was carried out with ammonia... 

HCN is the most preferred cyanide source in cyanohydrin synthesis. Besides HCN, several different cyanide sources, like potassium cyanide, are being used in biotransformation. Alternative methods for the safe handling of cyanides on a laboratory scale are, for instance, to use cyanide salts in solution. These solutions can be acidified and used as the aqueous layer in two-phase systems or the HCN can be extracted into the organic layer with the desired solvent for reactions in an organic phase. After the reaction, excess cyanide can readily be destroyed with iron(II) sulfate, or iron(III) chloride or bleach. Cyanide can also be presented in the form of organic cyano, such as acetone cyanohydrin [46] or cyanoformates. However, as claimed by Effenberger, some results could not be reproduced [47]. 

The reaction of 3/3-acetoxy-5a-cholest-8(14)-en-7-one with EtjAlCN was the key reaction in a synthesis of cholestanes containing an oxygenated 14a-substi-tuent. Cholest-4-en-3-one reacted smoothly with KCN-acetone cyanohydrin in benzene or acetonitrile containing 18-crown-6 to give the epimeric 5-cyano-cholestan-3-ones. An 11 -hydroxy-group increased the proportion of a-epox-ide produced in the reaction of 3-oxo-A -steroids with H202-0H . A 9a-fluorine substituent also influenced the stereochemistry of the reaction products and a... 

As well as almond meal, Sorghum bicolor shoots have also found application in the synthesis of aromatic cyanohydrins [55]. The enantiomeric purity obtained in transhydrocyanation experiments with acetone cyanohydrin as the cyanide source suffers from the high water content (>14% v/v) necessary for the decomposition of acetone cyanohydrin. In contrast, the application of HCN allows the use of low amounts of water (2% v/v), leading to yields and optical purities comparable with those obtained by the isolated enzymes. 

Initial preparative work with oxynitrilases in neutral aqueous solution [517, 518] was hampered by the fact that under these reaction conditions the enzymatic addition has to compete with a spontaneous chemical reaction which limits enantioselectivity. Major improvements in optical purity of cyanohydrins were achieved by conducting the addition under acidic conditions to suppress the uncatalyzed side reaction [519], or by switching to a water immiscible organic solvent as the reaction medium [520], preferably diisopropyl ether. For the latter case, the enzymes are readily immobilized by physical adsorption onto cellulose. A continuous process has been developed for chiral cyanohydrin synthesis using an enzyme membrane reactor [61]. Acetone cyanhydrin can replace the highly toxic hydrocyanic acid as the cyanide source [521], Inexpensive defatted almond meal has been found to be a convenient substitute for the purified (R)-oxynitrilase without sacrificing enantioselectivity [522-524], Similarly, lyophilized and powered Sorghum bicolor shoots have been successfully tested as an alternative source for the purified (S)-oxynitrilase [525],... 

Scheme 3.23 Asymmetric Strecker synthesis using a-amido sulfones with acetone cyanohydrin.

For the synthesis of cyanohydrins nature provides the chemist with R- and S-selective enzymes, the hydroxynitrile lyases (HNL) [4-7]. These HNLs are also known as oxynitrilases and their natural function is to catalyze the release of HCN from natural cyanohydrins like mandelonitrile and acetone cyanohydrin. This is a defense reaction of many plants. It occurs if a predator injures the plant cell. The reaction also takes place when we eat almonds. Ironically the benzaldhyde released together with the HCN from the almonds is actually the flavor that attracts us to eat them. 

In particular, the use of hydroxynitrile lyase has proved to be a general and reliable method for obtaining a-hydroxy nitriles of both configurations [22]. An interesting approach is the Upase- and baseacyl-cyanohydrin for a synthetic DKR [23]. This is a combination of two reaction systems the dynamic, base-catalyzed equiUbrium between acetone cyanohydrin, acetone, HCN, aldehyde and a racemic cyanohydrin and the lipase-catalyzed enantioselective and irreversible acylation of the hydroxyl group. The combination yields the... 

Acrylonitrile and methacrylonitrile can be obtained from petro-chemical olefins [2] by the noncatalytic reactions of HCN with acetaldehyde, acetone (cyanohydrin is the intermediate in these processes) or oxiranes (Z-cyanoetltanol being the intermediate in the acrylonitrile synthesis from ethylene oxide). 

Recently, the group of Herrera, Bernardi, and Ricci realized the enantioselective synthesis of protected a-amino nitriles from the corresponding a-amino sulfones 137, which act as effective precursors for the in situ generation of imines, by the use of acetone cyanohydrin (138) as a cyanide source using quinine-derived PTC 136 [64]. The aminonitriles 139 were produced with broad generality in 50-88% ee (Scheme 8.53). However, a similar protocol using KCN and TMSCN resulted in a lower ee value. 

Figure 2.63 Acetone cyanohydrin (a) and alternative routes (b) in the synthesis of methacrylic acid.

The ACH process has been improved by Mitsubishi Gas [332]. Acetone cyanohydrin is first hydrolyzed to 2-hydroxyisobutylamide with a Mn02 catalyst the amide is then reacted with methyl formate to produce the methyl ester of 2-hydroxyisobutyric acid, with co-production of formamide (this reaction is catalyzed by sodium meth-oxide). The ester is finally dehydrated with an Na-Y zeolite to methyl methacrylate. Formamide is converted into cyanhydric acid, which is used to produce acetone cyanohydrin by reaction with acetone. The process is elegant, since it avoids the co-production of ammonium bisulfate, and no net income of HCN is present. However, there are many synthesis steps, and a high energy consumption. 

Keywords a-Cyanoliydrin, a-Aminonitrile, Hydrogen cyanide. Acetone cyanohydrin, TMSCN, Lewis acid. Cyclic dipeptide. Peptide-metal complex, Strecker synthesis... 

Table 11.1-20). A very good illustration for the potential of enantiomer-differentiating acylation catalyzed by lipases is provided by the high-yield synthesis of a series of aromatic cyanohydrin acetates (la-g) from aldehydes, acetone cyanohydrin and vinyl acetate in the presence of Pseudomonas cepacia lipase and a basic anion-exchange resin in diisopropyl ether which proceeds under kinetic resolution coupled with in situ formation and racemization of the cyanohydrin representing a dynamic kinetic resolution. For further examples see Table 11.1-24. 

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