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Synthesis Strecker

Asymmetric Strecker reactions of aldimines and ketoimines are ideal means of synthesis of chiral a-amino acids including ot-quaternary amino acids [32]. Great endeavors have been devoted to the development of catalytic methods of this reaction [33]. [Pg.84]

Very recently, Feng and coworkers reported that a highly efficient catalytic asymmetric Strecker reaction with a broad substrate scope can be achieved by a [Pg.84]

R1=Alkyl, Aryl, R2=H R1=Alkyl, Aryl, R2=Alkyl, Aryl 90-99% yield 90-99% ee [Pg.86]

An a-amino acid 3 can be prepared by treating aldehyde 1 with ammonia and hydrogen cyanide and a subsequent hydrolysis of the intermediate a-amino nitrile 2. This so-called Strecker synthesis - is a special case of the Mannich reaction-, it has found application for the synthesis of a-amino acids on an industrial scale. The reaction also works with ketones to yield a, a -disubstituted a-amino acids. [Pg.270]

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  [Pg.270]

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  [Pg.270]

The a-aminonitrile can also be obtained by the treatment of the aldehyde with HCN followed by reaction of the formed cyanohydrin with ammonia. This method is known as Erlenmeyer modification. A more convenient route is to treat the aldehyde in one step with ammonium chloride and sodium cyanide (this mixture is equivalent to ammonium cyanide, which in turn dissociate into ammonia and HCN). This procedure is referred to as the Zelinsky-Stadnikott modification. The final step is the hydrolysis of the intermediate a-aminonitrile under acidic or basic conditions. [Pg.131]

Using strecker synthesis, disodium iminodiacetate (DSIDA) an intermediate for the manufacture is Monsantos Roundup (herbicide) was synthesised.  [Pg.131]

In the above synthesis hydrogen cyanide, a hazardous chemical is used and this requires special handling to minimise the risk to workers and the environment. An alternative green synthesis of DSIDA was developed by Monsanto. [Pg.132]


In the Strecker synthesis an aldehyde is converted to an a ammo acid with one more carbon atom by a two stage procedure m which an a ammo nitrile is an mterme diate The a ammo nitrile is formed by reaction of the aldehyde with ammonia or an ammonium salt and a source of cyanide ion Hydrolysis of the nitrile group to a car boxylic acid function completes the synthesis... [Pg.1121]

Aldehydes by reaction with ammonia and cyanide ion (the Strecker synthesis)... [Pg.1150]

If you synthesized the tnpeptide Leu Phe Ser from amino acids prepared by the Strecker synthesis how many stereoisomers would you expect to be formed ... [Pg.1153]

Strecker synthesis (Section 27 4) Method for prepanng amino acids in which the first step is reaction of an aldehyde with ammonia and hydrogen cyanide to give an amino nitnle which IS then hydrolyzed... [Pg.1294]

Strecker reaction Strecker synthesis Strengthening agent Strength testing Strepavidin Strep, pyogenes Cruz Strep tase... [Pg.933]

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... [Pg.221]

Other Reactions. The reaction of Thydioxybenzaldehyde with sodium cyanide and ammonium chloride, Strecker synthesis, yields /J-hydroxyphenylglycine [938-97-6] a key intermediate in the manufacture of semisynthetic penicillins and cephalosporins (see Antibiotics, p-LACTAMs). [Pg.506]

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. [Pg.411]

Raney nickel desulfurization has been applied especially to the synthesis of different kinds of amino acids. a-Amino acids have been prepared by the Strecker synthesis of substituted thiophenealdehydes, followed by desulfurization of the thiophene a-amino acids. a-Amino-n-enantic acid, a-amino-n-caprylic acid, and norleucin have been obtained in about 50% yield from the appropriate thiophene aldehydes. From the desulfurization of thiophene -amino acids, obtained from the reaction of thiophenealdehydes with malonic acid in ammonia, aliphatic j8-amino acids, isolated as acetates, have been obtained in high yields. The desulfurization of 3-nitrothiophenes, such as (232), in ammonia leads to y-substituted amino acids (233). ... [Pg.113]

Asymmetric synthesis of a,a-disubstituted a-amino acids via an intramolecular Strecker synthesis using l,4-oxazin-3-one derivatives as key intermediates 97YGK982. [Pg.264]

A variant of the Strecker synthesis is the Bucherer-Bergs reaction it gives better yields, and proceeds via formation of an intermediate hydantoin 5 ... [Pg.271]

Straight-chain alkane, 80 Strecker synthesis, 972 Structure, condensed, 22 electron-dot, 9 Kekule, 9 Lewis, 9 line-bond, 9 skeletal, 23... [Pg.1316]

Historically the Strecker synthesis of a-amino acids constitutes the first chemical access to this important class of compounds1, In this process, an aldehyde reacts with ammonia and hydrogen cyanide to form an a-amino nitrile2 which subsequently is hydrolyzed to give the corresponding amino acid3... [Pg.781]

Like the Strecker synthesis, the Ugi reaction also involves a nucleophilic addition to an imine as the crucial step in which the stereogenic center of an a-amino acid derivative is formed4. The Ugi reaction, also denoted as a four-component condensation (A), is related to the older Passerini reaction5 (B) in an analogous fashion as the Strecker synthesis is to cyanohydrin formation. In both the Ugi and the Passerini reaction, an isocyanide takes the role of cyanide. [Pg.782]

As has been outlined for the Strecker synthesis, the Ugi reaction also proceeds via initial formation of a Schiff base from an aldehyde and an amine. The imine intermediate is attacked by the isocyanidc, a process which is supported by protonation of the imine by the carboxylic acid component. The resulting a-amino nitrilium intermediate is immediately trapped by the carboxylate to give an 6>-acyl imidiate. All steps up to this stage are reversible. Only the final oxygen to nitrogen acyl shift is irreversible and delivers the A-acyl-a-amino amide as the thermodynamically favored product which contains two amide groups. [Pg.782]

The asymmetric Strecker synthesis of a-amino nitriles from Schiff bases of a-methylbenzyl-aminc is improved by the use of trimethylsilyl cyanide, instead of hydrogen cyanide and by promotion of the transformation with a Lewis acid, preferably zinc chloride43. Thus, from the butyraldimine 2, the amino nitrile is synthesized with a yield of 98.5% and an ee of 68.5%. [Pg.788]

In asymmetric Strecker synthesis ( + )-(45,55 )-5-amino-2,2-dimethyl-4-phenyl-l,3-dioxane has been introduced as an alternative chiral auxiliary47. The compound is readily accessible from (lS,25)-2-amino-l-phcnyl-l,3-propancdioI, an intermediate in the industrial production of chloramphenicol, by acctalization with acetone. This chiral amine reacts smoothly with methyl ketones of the arylalkyl47 or alkyl series48 and sodium cyanide, after addition of acetic acid, to afford a-methyl-a-amino nitriles in high yield and in diastereomerically pure form. [Pg.789]

This feature is also found for the Strecker synthesis with 3-methyl-4,4,4-trifiuorobutanol which yields the corresponding 5,5.5-trifluoroleucinonilriles in a diastereomeric ratio of 4 1 52. [Pg.792]

An efficient stereoselective Strecker synthesis of phenylglycine has been achieved using the tert-butyl ester tm-leucine as the chiral auxiliary. Its benzaldimine reacts with hydrogen cyanide in hexane at — 23 °C to furnish the ( )-diastereomer with the excellent diastereoselectivity of >98 254. [Pg.792]

The synthesis of a-amino acids by reaction of aldehydes or ketones with ammonia and hydrogen cyanide followed by hydrolysis of the resulting a-aminonitrile is called the Strecker synthesis. Enzymatic hydrolysis has been applied to the kinetic resolution of intermediate a-aminonitriles [90,91]. The hydrolysis of (rac)-phenylglycine nitrile... [Pg.145]

A particularly useful variation of this reaction uses cyanide rather than HCN. a-Amino nitriles can be prepared in one step by the treatment of an aldehyde or ketone with NaCN and NH4CI. This is called the Strecker synthesisand it is a special case of the Mannich reaction (16-15). Since the CN is easily hydrolyzed to the acid, this is a convenient method for the preparation of a-amino acids. The reaction has also been carried out with NH3-I-HCN and with NH4CN. Salts of primary and secondary amines can be used instead of NH to obtain N-substituted and N,N-disubstituted a-amino nitriles. Unlike 16-51, the Strecker synthesis is useful for aromatic as well as aliphatic ketones. As in 16-51, the Me3SiCN method has been used 64 is converted to the product with ammonia or an amine. ... [Pg.1240]


See other pages where Synthesis Strecker is mentioned: [Pg.276]    [Pg.271]    [Pg.114]    [Pg.270]    [Pg.270]    [Pg.972]    [Pg.781]    [Pg.782]    [Pg.783]    [Pg.785]    [Pg.344]    [Pg.1240]   
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Alanine Strecker synthesis

Aldehydes in Strecker synthesis of amino acids

Aldimine asymmetric Strecker amino acid synthesis

Amino Strecker synthesis

Amino Strecker-cyanohydrin synthesis

And the Strecker synthesis

Asymmetric Strecker amino acid synthesis

Asymmetric Strecker synthesis

Carbohydrates Strecker amino acid synthesis

Chiral auxiliaries Strecker amino acid synthesis

Cyanation Strecker synthesis

Cyanohydrins, Strecker amino acid synthesis

Enantioselectivity Strecker amino acid synthesis

Glycine, Strecker amino acid synthesis

Homogeneous Strecker synthesis

Hydrocyanation Strecker synthesis

Hydrolysis Strecker amino acid synthesis

Imine products Strecker amino acid synthesis

Mannich reaction, Strecker amino acid synthesis

Peptide-catalysed Cyanations Cyanhydrin Synthesis and Strecker Reactions

STRECKER Aminoacid synthesis

Stereoselectivity Strecker synthesis

Steroid Strecker synthesis

Strecker

Strecker amino acid synthesis

Strecker amino acid synthesis mechanism

Strecker nitrile synthesis

Strecker solid phase synthesis

Strecker synthesis catalysts

Strecker synthesis conditions

Strecker synthesis enantioselective

Strecker synthesis, of amino acids

Strecker-cyanohydrin synthesis

Strecker-type synthesis

Strecker’s synthesis

The Strecker synthesis

Trimethylsilyl cyanide , Strecker amino acid synthesis

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