Lithium aluminum cyanide

Mescaline a hallucinogenic amine obtained from the peyote cactus has been synthesized in two steps from 3 4 5 trimethoxybenzyl bromide The first step is nucleophilic substitution by sodium cyanide The second step is a lithium aluminum hydnde reduction What is the structure of mescaline" ... 

High yields of optically active cyanohydrins have been prepared from hydrogen cyanide and carbonyl compounds using an enzyme as catalyst. Reduction of these optically active cyanohydrins with lithium aluminum hydride in ether affords the corresponding substituted, optically active ethanolamine (5) (see Alkanolamines). 

The starting material was prepared in a yield of 5B% by reduction of the corresponding cyanohydrin. It in turn was prepared from 1-(2-phenylethyl)-4-plperidone and potassium cyanide to give the cyanohydrin which was reduced by lithium aluminum hydride. 

Woodward s strychnine synthesis commences with a Fischer indole synthesis using phenylhydrazine (24) and acetoveratrone (25) as starting materials (see Scheme 2). In the presence of polyphosphor-ic acid, intermediates 24 and 25 combine to afford 2-veratrylindole (23) through the reaction processes illustrated in Scheme 2. With its a position suitably masked, 2-veratrylindole (23) reacts smoothly at the ft position with the Schiff base derived from the action of dimethylamine on formaldehyde to give intermediate 22 in 92% yield. TV-Methylation of the dimethylamino substituent in 22 with methyl iodide, followed by exposure of the resultant quaternary ammonium iodide to sodium cyanide in DMF, provides nitrile 26 in an overall yield of 97%. Condensation of 2-veratryl-tryptamine (20), the product of a lithium aluminum hydride reduction of nitrile 26, with ethyl glyoxylate (21) furnishes Schiff base 19 in a yield of 92%. 

A different approach involving cyanohydrin formation from the 3-keto sugar was also explored in the D-Fru series (Scheme 17). A mixture of epimeric cyanohydrins was quantitatively formed by reaction with sodium cyanide in methanol, albeit without stereoselectivity. Chromatographic separation of (R)- and (A)-isomers was straightforward and the former epimer was selected to exemplify the two-step transformation into an OZT. Reduction of this nitrile by lithium aluminum hydride led to the corresponding aminoalcohol, which was further condensed with thiophosgene to afford the (3i )-spiro-OZT in ca. 30% overall yield. Despite its shorter pathway, the cyanohydrin route to the OZT was not exploited further, mainly because of the disappointing yields in the last two steps. 

Nitriles of keto acids are reduced with lithium aluminum hydride at both functions. Benzoyl cyanide afforded 2-amino-1-phenylethanol in 86% yield... 

Diclofenac Diclofenac, 2-[(2,6-dichlorophenyl)-amino]-phenylacetic acid (3.2.42), is synthesized from 2-chIorobenzoic acid and 2,6-dichloroaniline. The reaction of these in the presence of sodium hydroxide and copper gives iV-(2,6-dichlorophenyl)anthranyIic acid (3.2.38), the carboxylic group of which undergoes reduction by lithium aluminum hydride. The resulting 2-[(2,6-dicholorphenyl)-amino]-benzyl alcohol (3.2.39) undergoes further chlorination by thionyl chloride into 2-[(2,6-dichlorophenyl)-amino]-ben-zylchloride (3.2.40) and further, upon reaction with sodium cyanide converts into... 

Mecamylamine Mecamylamine, M2,3,3-tetramethylnorboman-2-ylamine (14.2. 2), is synthesized from 2,3,3-trimethylnorbomen-2, which is reacted in a Ritter reaction conditions with hydrogen cyanide in concentrated snlfuric acid, giving 2,3,3-trimethylnorbor-nan-2-ylformylamine (14.2.1), the reduction of which by lithium aluminum hydride leads to mecamylamine (14.2.2) [32,33]. 

In view of the multicomponent nature of the tandem [4 + 2] / [3 + 2] cycloaddition, the potential for a combinatorial approach to the synthesis of nitroso acetals has been investigated on solid-phase supports. The incorporation of either the dipolarophile or the starting nitroalkene on a Wang-type resin is compatible with the tandem cycloaddition promoted at high pressures (Schemes 2.28 and 2.29). The solid-supported nitroso acetals are subsequently liberated (in moderate yields from the staring nitroalkene) upon the addition of a catalytic amount of potassium cyanide in triethylamine and methanol or by reduction with lithium aluminum hydride (LAH) (261,264). 

Discovery. These catalysts were discovered during a study of the use of transition metal cyanides in combination with metal alkyl and hydride reducing agents in polymerizations. The combination of nickel cyanide and lithium aluminum hydride complexed very strongly with tetrahydrofuran. A similar complexing action occurred with propylene oxide and nickel hexacyanoferrate(II)-lithium aluminum hydride. This led to speculation as to the role of the double-metal cyanide itself. 

The first step incorporates generation of a tnllalc leaving group in 35, which is then replaced by a cyanide ion to give 36. Lithium aluminum hydride and sulfuric acid react lo lorm aluminum hydride, capable of selectively reducing the nitrile lo primary amine 9... 

Sodium cyanide reacts with alkyl bromides by the SN2 mechanism. Reduction of the cyano group with lithium aluminum hydride yields a primary amine. This reveals the structure of mescaline to be 2-(3,4,5-trimethoxyphenyl)ethylamine. 

Given the structure or name of an aldehyde or ketone, write an equation for its reaction with the following nucleophiles alcohol, cyanide ion, Grignard reagent or acetylide, hydroxylamine, hydrazine, phenylhydrazine, 2,4-dinitrophenylhydrazine, primary amine, lithium aluminum hydride, and sodium borohydride. 

The radiolabel was introduced by displacement of a quaternary amine with potassium 14C-cyanide to give a nitrile. The nitrile was readily converted to indole-3-acetic acid by hydrolysis with 20% aqueous potassium hydroxide. Reduction of the indole-3-acetic acid derivative with lithium aluminum hydride in tetrahydrofuran gave a typtophol with 95% yield. 

By contrast, addition of hydrogen cyanide to J -pyrrolines yields stable nitriles, which are reduced by lithium aluminum hydride to diamines and can be saponified to acids318 (Scheme 14). 

Formation and Reduction of Nitriles Like the azide ion, cyanide ion (- C=N ) is a good Sn2 nucleophile it displaces leaving groups from unhindered primary and secondary alkyl halides and tosylates. The product is a nitrile (R—C=N), which has no tendency to react further. Nitriles are reduced to primary amines by lithium aluminum hydride or by catalytic hydrogenation. 

Tetrahydropyridazines with unsubstituted NH groups behave as secondary amines the double bond has been hydrogenated with lithium aluminum hydride and addition of hydrogen cyanide is known. Oxidation of 3,6-diphenyl-1,4,5,6-tetrahydro-pyridazine with lead dioxide results in aromatization. ... 

Reduction may also be brought about by sodium and alcohol, although extensive cleavage, of the cyanide group may occur, viz., RCN— RH + NaCN. Lithium aluminum hydride has been successfully employed for the reduction of aliphatic and aromatic nitriles as well as several cyanides in the thiophene series. ... 

Dichloro(l, 3-propanediyl)platinum and its bis(pyridine) derivative have been studied by a number of authors. Dichloro(l,3-propanediyl)platinum, and the corresponding substituted 1,3-propanediyl platinum compounds release the parent cyclopropane on treatment with potassium cyanide, potassium iodide, a tertiary phosphine, carbon monoxide, and other ligands.2,6 Reduction by means of hydrogen or lithium aluminum hydride yields chiefly isomeric substituted propanes. Dichlorobis(pyridine)(l,3-propanediyl)platinum in refluxing benzene yields a pyridinium ylid complex, - (CH3CH2CHNC5Hs)-PtpyCla. 

Preparation of Derivatives. Enoate derivatives are prepared from the corresponding chiral alcohol by treatment with acry-loyl chloride in the presence of Triethylamine and catalytic 4-Dimethylaminopyridine or the appropriate carboxylic acid chloride and Silveril) Cyanide. Alkynyl ethers are readily available from the potassium alkoxide by treating with Trichloroethylene, in situ dechlorination with n-Butyllithium, and electrophilic trapping. Trapping the intermediate anion with a proton source or lodomethane followed by Lindlar reduction of the alkynyl ether affords the corresponding vinyl and l-(Z)-propenyl ether, respectively, while reduction of the alkynyl ether with Lithium Aluminum Hydride affords the l-( )-propenyl ether. 

---