Nitriles cyanohydrins

Discovery of the chain-lengthening sequence was initiated by the observation of Heinrich Kiliani in 1886 that aldoses react with HCN to form cyanohydrins (Section 19.6). Emil Fischer immediately realized the importance of Kiliani s discovery and devised a method for converting the cyanohydrin nitrile group into an aldehyde. 

To aqcuire more insight in amide formation we undertook to study the hydrolysis of enantiomerically pure cyanohydrins. Nitrile le racemises too readily but the stereochemical integrity of (R)- and (S)-la could be maintained with careful adjustment of the reaction conditions (pH 6, 0°C). Thus, enantiomerically pure (R)- and (S)-la were subjected to hydrolysis in the presence of PfNLase (see Figure 16.9) [5]. It became clear that only 11% of amide was formed from the (R)-enan-tiomer, whereas the (S)-enantiomer was hydrolyzed into 55% amide and 45% acid under otherwise identical conditions (see Figure 16.9). Stereochemical integrity was fully maintained under the reaction conditions and 3a and 4a were formed with complete retention of configuration, as would be expected. 

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.). 

In substitutive lUPAC nomen clature cyanohydrins are named as hydroxy deriva tives of nitriles Because ni trile nomenclature will not be discussed until Section 20 1 we will refer to cyanohydrins as derivatives of the parent aldehyde or ketone as shown in the ex amples This conforms to the practice of most chemists... 

Nitrile groups m cyanohydrins are hydrolyzed under conditions similar to those of alkyl cyanides Cyanohydrin formation followed by hydrolysis provides a route to the preparation of a hydroxy carboxylic acids... 

Nitriles contain the —C=N functional group We have already discussed the two mam procedures by which they are prepared namely the nucleophilic substitution of alkyl halides by cyanide and the conversion of aldehydes and ketones to cyanohydrins Table 20 6 reviews aspects of these reactions Neither of the reactions m Table 20 6 is suitable for aryl nitriles (ArC=N) these compounds are readily prepared by a reaction to be dis cussed m Chapter 22... 

As a class of compounds, the two main toxicity concerns for nitriles are acute lethality and osteolathyrsm. A comprehensive review of the toxicity of nitriles, including detailed discussion of biochemical mechanisms of toxicity and stmcture-activity relationships, is available (12). Nitriles vary broadly in their abiUty to cause acute lethaUty and subde differences in stmcture can greatly affect toxic potency. The biochemical basis of their acute toxicity is related to their metaboHsm in the body. Following exposure and absorption, nitriles are metabolized by cytochrome p450 enzymes in the Hver. The metaboHsm involves initial hydrogen abstraction resulting in the formation of a carbon radical, followed by hydroxylation of the carbon radical. MetaboHsm at the carbon atom adjacent (alpha) to the cyano group would yield a cyanohydrin metaboHte, which decomposes readily in the body to produce cyanide. Hydroxylation at other carbon positions in the nitrile does not result in cyanide release. 

The propensity of nitriles to release cyanide subsequent to metaboHsm is the basis of their acute toxicity. Nitriles that form tertiary radicals at their alpha carbon atoms (eg, isobutyronitrile, 2-methylbutyronitrile) are substantially more acutely lethal than nitriles that form secondary radicals at their alpha carbons (eg, butyronitrile, propionitnle). Cyanohydrins are acutely toxic because they are unstable and release cyanide quickly. Alpha-aminonitriles are also acutely toxic, presumably by analogy with cyanohydrins. 

A cyanohydrin is an organic compound that contains both a cyanide and a hydroxy group on an aUphatic section of the molecule. Cyanohydrias are usually a-hydroxy nitriles which are the products of base-cataly2ed addition of hydrogen cyanide to the carbonyl group of aldehydes and ketones. The lUPAC name for cyanohydrias is based on the a-hydroxy nitrile name. Common names of cyanohydrias are derived from the aldehyde or ketoae from which they are formed (Table 1). 

Cyanohydrins can react either at the nitrile group or at the hydroxyl group. 

Nitrile Group. Hydrolysis of the nitrile group proceeds through the amide to the corresponding carboxyUc acid. Because cyanohydrins are unstable at high pH, this hydrolysis must be cataly2ed by acids. In cases where amide hydrolysis is slower than nitrile hydrolysis, the amide may be isolated. 

Catalytic hydrogenation of the nitrile function of cyanohydrins can give amines. As in the case of ordinary nitriles, catalytic reduction of cyanohydrins can yield a mixture of primary, secondary, and tertiary amines. Addition of acid or acetic anhydride to the reaction medium minimizes formation of secondary or tertiary amines through formation of the amine salt or acetamide derivative of the primary amine. 

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. 

Cyanohydrins react with hydrogen haUdes or PCl to give a-halo nitriles which can be further hydrolyzed to the a-halo carboxyUc acids. The a-hydroxy group of cyanohydrins can be esterified with an acid or acid chloride. Dehydration of cyanohydrins with phosphoms pentoxide gives >80% yields of alkylacrylonitriles (8). 

Cyanohydrins are highly toxic by inhalation or ingestion, and moderately toxic through skin absorption (21). AH a-hydroxy nitriles are potential sources of hydrogen cyanide or cyanides and must be handled with considerable caution. Contact with the skin and inhalation should be rigorously avoided. Special protective clothing should be worn and any exposure should be avoided (18,20). The area should be adequately ventilated. Immediate medical attention is essential in case of cyanohydrin poisoning. 

Acetaldehyde Cyanohydrin. This cyanohydrin, commonly known as lactonitnle, is soluble in water and alcohol, but insoluble in diethyl ether and carbon disulfide. Lactonitnle is used chiefly to manufacture lactic acid and its derivatives, primarily ethyl lactate. Lactonitnle [78-97-7] is manufactured from equimolar amounts of acetaldehyde and hydrogen cyanide containing 1.5% of 20% NaOH at —10 20 ° C. The product is stabili2ed with sulfuric acid (28). Sulfuric acid hydroly2es the nitrile to give a mixture of lactic acid [598-82-3] and ammonium bisulfate. 

Cyanohydrin trimethylsilyl ethers are generally useful as precursors of ctir-bonyl anion equivalents and as protected forms of aldehydes. Direct conversion of p-anisaldehyde into 0-TRIMETHYLSILYL-4-METH0XYMANDEL0-NITRILE employs a convenient in situ generation of trimethylsilyl cyanide from chlorotnmethylsilane A general synthesis of allemc esters is a variant of the Wittig reaction. Ethyl (triphenylphosphoranylidene)acetate converts pro-pionyl chloride into ETHYL 2,3-PENTADlENOATE. 

Acetone cyanohydrin (Oxyisobutyric nitrile) (CH3)2C(0H)CN Highly toxic by inhalation or ingestion Irritating and moderately toxic upon skin contact Readily decomposes to HCN and acetone at 1 20°C, or at lower temperatures when exposed to alkaline conditions Colourless combustible liquid Elash point 73°C Ignition temperature 68.7°C Completely soluble in water... 

Cyanides are dangerously toxic materials that can cause instantaneous death. They occur in a number of industrial situations but are commonly associated with plating operations, and sludges and baths from such sources. Cyanide is extremely soluble and many cyanide compounds, when mixed with acid, release deadly hydrogen cyanide gas. Cyanide is sometimes formed during the combustion of various nitrile, cyanohydrin, and methacrylate compounds. Cyanides (CN ) are commonly treated by chlorine oxidation to the less toxic cyanate (CNO ) form, then acid hydrolyzed to COj and N. Obviously, care should be taken that the cyanide oxidation is complete prior to acid hydrolysis of the cyanate. 

The requisite starting cyanohydrin is readily prepared from a 20-keto-pregnane substitution at C-21 has no effect on the success of this step. However, the stability of the cyanohydrin is markedly dependent on other features of the molecule thus a 3-acetate confers greater stability than the free alcohol, and a 3-ketone is so unstable that subsequent dehydration with phosphorus oxychloride gives poor yields of the A -unsaturated nitrile. 

Hydroxy-20-cyanohydrins can be oxidized to 3-ketones in good yield with chromic acid, and the osmate ester of the unsaturated nitrile is also stable to this oxidant. " After hydrolysis of the osmate ester, the new 17-hydroxy-20-cyanohydrin which is presumably formed cannot be isolated, but loses hydrogen cyanide during the hydrolysis, and only the 17a-hydroxy-20-ketone is obtained. 

Section 20.18 Nitriles are prepared by nucleophilic substitution (Sn2) of alkyl halides with cyanide ion, by converting aldehydes or ketones to cyanohydrins (Table 20.6), or by dehydration of fflnides. 

The formation of a-amino nitrile 2 is likely to proceed via a cyanohydrin 4 (an a-hydroxy nitrile) as intermediate, which is formed by the addition of hydrogen cyanide to the aldehyde 1 ... 

Reaction of cyanohydrin 4 with ammonia leads to formation of a-amino nitrile 2, which can easily be hydrolyzed to give the corresponding a-amino acid 3 ... 

Antispasmodic activity, interestingly, is maintained even in the face of the deletion of the ethanolamine ester side chain. Reaction of anisaldehyde with potassium cyanide and dibutylamine hydrochloride affords the corresponding a-aminonitrile (72) (a functionality analogous to a cyanohydrin). Treatment with sulfuric acid hydrolyzes the nitrile to the amide to yield ambucet-amide (73). ... 

One of the earliest preparations of this ring system starts with displacement of the hydroxyl of benzaldehyde cyanohydrin (125) by urea. Treatment of the product (126) with hydrochloric acid leads to addition of the remaining urea nitrogen to the nitrile. There is thus obtained, after hydrolysis of the imine (127), the hydantoin (128). Alkylation by means of ethyl iodide affords ethotoin (129)... 

A thiazole derivative that incorporates a fragment of the amphetamine molecule shows some CNS stimulant activity more specifically, the compound antagonizes the depression caused by overdoses of barbiturates and narcotics. Reaction of benzalde-hyde with sodium cyanide and benzenesulfonyl chloride gives the toluenesulfony1 ester of the cyanohydrin (141). Reaction of this with thiourea leads directly to aminophenazole (143) It is probable the reaction proceeds by displacement of the tosylate by the thiourea sulfur to give 142 addition of the amino group to the nitrile followed by tautomerization affords the observed product. ... 

In a departure from the prototype molecule, the benzylpiperi-done is first converted to the corresponding aminonitrile (a derivative closely akin to a cyanohydrin) by treatment with aniline hydrochloride and potassium cyanide (126). Acid hydrolysis of the nitrile affords the corresponding amide (127). Treatment with formamide followed by reduction affords the spiro oxazinone... 

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