Bucherer hydantoin synthesis

Benzilic acid rearrangement Benzoin reaction (condensation) Blanc chloromethylation reaction Bouveault-Blanc reduction Bucherer hydantoin synthesis Bucherer reaction Cannizzaro reaction Claisen aldoi condensation Claisen condensation Claisen-Schmidt reaction. Clemmensen reduction Darzens glycidic ester condensation Diazoamino-aminoazo rearrangement Dieckmann reaction Diels-Alder reaction Doebner reaction Erlenmeyer azlactone synthesis Fischer indole synthesis Fischer-Speior esterification Friedel-Crafts reaction... 

Bucherer hydantoin synthesis, 843, 844 Bucherer reaction, 561, 568, 569 Bumping of liquids, 3, 4... 

Benzilic acid rearrangement Benzoin reaction (condensation) Blanc chloromethylation reaction Bouveault-Blanc reduction Bucherer hydantoin synthesis. Bucherer reaction. . ... 

The above reaction is an example of Bucherer s hydantoin synthesis. The following mecJiavism has been proposed ... 

The first improvement of the Bucherer-Bergs reaction was the Bucherer-Lieb variation using the diluted alcoholic solution as described at the end of section 7.2.2. The Bucherer-Lieb variation is possibly the most popular process for synthesizing hydantoins. Another notable variation is the Henze modification using fusing acetamide as the solvent in place of water, benzene or 50% alcohol. Recently, ultrasound-promoted hydantoin synthesis has been reported to accelerate the reaction. 

Monosubshtuted hydantoins are a-amino acids cyclically protected at both the carboxyl- and the a-amino group. They can be easily prepared from an aldehyde and isocyanate or by the Bucherer-Bergs synthesis and similar methods. Indeed, the hydantoin synthesis is also a prachcal method for the preparahon of the racemic amino acid. Enzymes belonging to the dihydro-pyrimidinase family hydrolyze hydantoins to the carbamoyl amino acid. The latter can be hydrolyzed in turn to the amino acid by a second enzyme, a carbamoylase. Both enzymes can discriminate between enantiomers and, if their action is cooperative, either the L- or the D-amino acid can be obtained (Scheme 13.10) [36]. What makes the system of special interest is that the proton in the 5-position of the hydantoin ring (it will become the a-hydrogen in the a-amino acid) is considerably more acidic than conventional protons in amino acid esters or amides and much more acidic than the amino acid itself. Thus, the hydantoin can be often racemized in situ at slightly basic pH where the enzymes are stiU stable and active. If these condihons are met. 

The Bucherer-Bergs hydantoin synthesis has been employed to build spiro compounds 221 as 5-HTlA modulators [81]. The compounds were prepared from... 

The Bucherer-Bergs synthesis is of general application to carbonyl compounds, employing potassium cyanide and ammonium carbonate.1,4 Carbonyl derivatives such as semicarbazones, thiosemicarbazones, oximes, azines, phenylhydrazones, imidazolidines, and azomethines also are readily converted directly to the corresponding hydantoins 44 The extent to which the reaction occurs appears unrelated to the hydrolytic stability of the starting material. The proposed mechanism is given in Scheme 1. 

If cyanohydrins are treated with ammonium carbonate instead of ammonia, 5-substituted hydantoins are obtained, usually in very good yield (the Bucherer-Henze synthesis) 979... 

The H CN (or CN, if the reaction is done under basic conditions) synthon has been mainly used to extend the carbon chain by one carbon. For example, cyanide ion has been used in the synthesis of amino acids labelled in the carboxylate group. This is accomplished using the high pressure-high temperature modification of the Bucherer-Strecker synthesis. In this reaction, bisulphite addition complex of an aldehyde reacts with cyanide ion in the presence of ammonium carbonate to form a hydantoin, which is then converted into the amino acid by basic hydrolysis (equation 61). 

Other references related to the Bucherer-Bergs hydantoin synthesis are cited in the literature. ... 

An interesting and useful example of synthesis of a-amino acids has been recently reported by Wuts and coworkers, describing a scalable process to prepare the INOS inhibitor PHA-399733 42 using the Bucherer-Bergs hydantoin synthesis as key step to introduce the amino acid function present in the final skeleton (Scheme 10.11) [41]. The methodology was applicable to the isolation of 39.9 kg (75% yield) of the racemic hydantoin 41, and the desired enantiomer was then opened in basic conditions giving the corresponding amino acid moiety. 

In a German patent issued in 1929, Bergs described a synthesis of some 5-substituted hydantoins by treatment of aldehydes or ketones (1) with potassium cyanide, ammonium carbonate, and carbon dioxide under several atmospheres of pressure at 80°C. In 1934, Bucherer et al. isolated a hydantoin derivative as a by-product in their preparation of cyanohydrin from cyclohexanone. They subsequently discovered that hydantoins could also be formed from the reaction of cyanohydrins (e.g. 3) and ammonium carbonate at room temperature or 60-70°C either in water or in benzene. The use of carbon dioxide under pressure was not necessary for the reaction to take place. Bucherer and Lieb later found that the reaction proceeded in 50% aqueous ethanol in excellent yields for ketones and good yields for aldehydes. ... 

In summary, the Bucherer-Bergs reaction converts aldehydes or ketones to the corresponding hydantoins. It is often carried out by treating the carbonyl compounds with potassium cyanide and ammonium carbonate in 50% aqueous ethanol. The resulting hydantoins, often of pharmacological importance, may also serve as the intermediates for amino acid synthesis. 

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

The scope of the reaction depends on the availability of the starting aldehyde (or ketone). A drawback is the toxicity of the hydrogen cyanide used as reactant. A variant of the Strecker synthesis is the Bucherer-Bergs reaction it gives better yields, and proceeds via formation of an intermediate hydantoin 5 ... 

Synthesis From Aldehydes and Ketones. Treatment of aldehydes and ketones with potassium cyanide and ammonium carbonate gives hydantoins in a one-pot procedure (Bucherer-Bergs reaction) that proceeds through a complex mechanism. Some derivatives, like oximes, semicarbazones. Iliiosetricarbazones. and others, are also suitable starting materials. 

Fig. 7.11. Synthesis of racemic methionine by means of the Bucherer modification of the Strecker synthesis. The first step of the reaction does not stop at the stage the step of the a-aminonitrile but yields a hydantoin (B mechanistic details Figure 7.12). The second step—via the anion C of a hydantoin acid—leads to the formation of the anion E of methionine, which can be pro-tonated during workup to yield the uncharged methionine (D).

Fig. 7.12. Mechanism for the formation of hydantoin from 3-(methylthio)propional-dehyde, ammonium hydrogen carbonate and sodium cyanide, the initial reaction of the Strecker/Bucherer synthesis of methionine according to Figure 7.11.

Several hydrolytic enzymes other than esterases have been applied for synthetic purposes. One important subject is the chemoenzymatic preparation of amino acids. An industrial method for the synthesis of unnatural d- or L-amino acids employs the enzymatic hydrolysis of hydantoins, prepared by Bucherer-Bergs condensation using either D- or L-hydantoinase (cf Section 3.2.1.4) [33]. Another efficient method of preparing natural and unnatural amino acids is the two-step synthesis which features a Pd-catalyzed amidocarbonylation (eq. (2) cf Section 2.1.2.4) to afford racemic A-acyl amino acids followed by enantioselective hydrolysis using various acylases [34]. 

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