Chiral cyanohydrin acidic conditions

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],... 

A partial reduction of O-protected chiral cyanohydrins is also possible by reaction with Reformatsky reagents (Blaise reaction). The primarily formed imino intermediates can be hydrolyzed under very mild conditions to give the enamines ( )-15, which yield by treatment with strong acids the tetronic acids (R)-16 (Scheme 9) [39,40]. 

Nucleophilic substitutions of 0-activated 2-hydroxy carboxylic acids and esters, respectively, are well established, but little is known about the analogous reactions of activated cyanohydrins. Chiral 2-sulfonyloxynitriles, accessible from non-racemic cyanohydrins, have a relatively high configurational stability. They react with nucleophiles under very mild conditions under inversion of configuration (Scheme 8). ° ... 

Aromatic and aliphatic aldehydes in the presence of dialkylamines and an equivalent of acid such as hydrochloric, perchloric or p-toluenesulfonic acid give iminium salts, which add cyanide ion to form a-(dialkylamino)nitriles. An alternative preparation involves the reaction of the aldehyde with dialkylamines in the presence of acetone-cyanohydrin, a-(A, -dialkylamino)isobutyronitiiles, diethyl phosphorocyanidate or TMS-CN. Another route to a-aminonitrile starts with an aldehyde, the salt of an amine and KCN in organic solvents under solid-liquid two-phase conditions by combined use of alumina and ultrasound. Chiral a-aminonitriles were prepared by Strecker-type reactions, cyano-silylation of Schiffs bases, amination of a-siloxynitriles or from an A -cyanomethyl-l,3-oxazolidine synthon. Reaction of tertiary amines with CIO2 in the presence of 5.1 mol equiv. of aqueous NaCN as an external nucleophile affords a-aminonitrile. °... 

Amines. Chiral a-amino acids are obtained from cyanohydrins via a Mitsunobu reaction employing A-f-butoxycarbonyl-A-(2-trimethylsilyl)ethylsulfonamide as the nucleophile. The a-aminonitrile derivatives thus generated are hydrolyzed with acid. By means of an intramolecular displacement (3-hydroxy acids are transformed into (3-amino acids. Thus, subjecting the derived 0-benzylhydroxamides to Mitsunobu reaction conditions leads to (3-lactams which are readily processed (LiOH H, Pd/C). 

Subsequently, the Feng group developed an enantioselective cyanosilylation of ketones by a catalytic double-activation catalyst system composed of chiral (J ,J )-salen 16-triethylaluminium complex and N-oxide 17 (Scheme 19.10). High catalytic turnovers (200 for aromatic ketones, 1000 for aliphatic ones) with high enantioselectivity (up to 94% enantiomeric excess for aromatic ketones, up to 90% enantiomeric excess for aliphatic ones) were achieved under mild reaction conditions. Based on the control experiments, a double-activation model was suggested (Scheme 19.10). The chiral aluminium complex performed as a Lewis acid to activate the ketone, whereas the N-oxide acted as a Lewis base to activate trimethylsilyl cyanide and form an isocyanide species. The activated nucleophile and ketone attracted and approached each other, and so the transition state was formed. The intramolecular transfer of cyanide to the carbonyl group gives the product cyanohydrin O-TMS ether. 

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