Hydantoins preparation

Chemically synthesised D,L-hydantoins prepared from the corresponding aldehydes via die Bucherer Berg reaction are converted by the bacterial cells (Bacillus brevis), containing a D-spedfic hydantoinase, to a mixture of D-N-carbamoyl amino acid and L-hydantoin. The latter compound undergoes rapid and spontaneous racemisation under the conditions of the reaction, therefore, in principle 100% of the hydantoin is converted into the D-N-carbamoyl compound. The D-amino add is obtained after treatment of the D-N-carbamoyl compound with nitrous add. This process is operated on an industrial scale by the Japanese firm Kanegafuchi. 

Another approach for the synthesis of enantiopure amino acids or amino alcohols is the enantioselective enzyme-catalyzed hydrolysis of hydantoins. As discussed above, hydantoins are very easily racemized in weak alkaline solutions via keto enol tautomerism. Sugai et al. have reported the DKR of the hydantoin prepared from DL-phenylalanine. DKR took place smoothly by the use of D-hydantoinase at a pH of 9 employing a borate buffer (Figure 4.17) [42]. 

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]. 

Cy alkyl ester of PEG separation of PEG, monoester, diester single peak for each Mono- and dioleate of 10-mole ethoxylate of N,N -his (2-hydroxyethyl)-5,5-dimethyl-hydantoin preparative separation of mono- and diester and free ethoxylate Mono- and di-heptanoate of tetraethylene glycol determination of mono- and diester, heptanoic acid, and tetraethylene glycol... 

The imide proton N-3—H is more acidic than N-1—H and hence this position is more reactive toward electrophiles in a basic medium. Thus hydantoins can be selectively monoalkylated at N-3 by treatment with alkyl haUdes in the presence of alkoxides (2,4). The mono-A/-substituted derivatives (5) can be alkylated at N-1 under harsher conditions, involving the use of sodium hydride in dimethylform amide (35) to yield derivatives (6). Preparation of N-1 monoalkylated derivatives requires previous protection of the imide nitrogen as an aminomethyl derivative (36). Hydantoins with an increased acidity at N-1—H, such as 5-arylmethylene derivatives, can be easily monoalkylated at N-3, but dialkylation is also possible under mild conditions. 

Similar alkylations may be effected on oxygen. l-(2-Chloroethyl)imidazolidin-2-one (312) when treated with potassium hydroxide or sodium hydride underwent ring closure to the tetrahydroimidazo[2,l-6]oxazole (313) (57JA5276). This approach can be used for the preparation of bicyclic hydantoins and the corresponding dihydro derivatives of (313) using the mesylate of (312) and NaH (77JHC5U, 79JMC1030). 

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. ... 

The other most important synthetic utility of the Bucherer-Bergs reaction is the preparation of amino acids from the hydrolysis of hydantoins. When carbonyl 1 was symmetrical, the Henze modification gave hydantoin 2, which was then hydrolyzed to the... 

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)... 

Hydantoin can be prepared in a variety of ways, notably from glycine2 or ethyl aminoacetate8 and potassium cyanate. The checkers used Eastman Kodak white label hydantoin. 

Hydantoins have been prepared starting from aminoesters that were first transformed into the corresponding carbanilides (ureas) 144 under standard conditions and then cyclized under microwave irradiation in the presence of Ba(OH)2 in DMF in 2 min and in yields ranging from 91 to 80% (Scheme 51) [91,92], Simple and more complex hi- and tricyclic compounds, such as 145-147, have been prepared with this method that seems versatile and applicable to many substrates. 

Dantrolene is the mainstay of MH treatment. It has long been available for the treatment of muscle spasm in cerebral palsy and similar diseases. It is a hydantoin derivative that was first synthesized in 1967, and reported to be effective in the treatment of porcine MH in 1975. Also in 1975, dantrolene was shown to be more effective than procainamide in the treatment of human MH, which until that time was the drug of choice. However, the intravenous preparation was not made available until November 1979. It significantly lowered mortality. The half-life of dantrolene is estimated to be 6-8 hr. Dantrolene s primary mode of action is the reduction in calcium release by the sarcoplasmic reticulum. Dantrolene also exerts a primary antiarrhythmic effect by increasing atrial and ventricular refractory periods. Side effects of dentrolene include hepatotoxicity, muscle weakness, ataxia, blurred vision, slurred speech, nausea, and vomiting. Dantrolene is not contraindicated in pregnancy, but it does cross into breast milk and its effect on the neonate is unknown. 

For successful DKR two reactions an in situ racemization (krac) and kinetic resolution [k(R) k(S)] must be carefully chosen. The detailed description of all parameters can be found in the literature [26], but in all cases, the racemization reaction must be much faster than the kinetic resolution. It is also important to note that both reactions must proceed under identical conditions. This methodology is highly attractive because the enantiomeric excess of the product is often higher than in the original kinetic resolution. Moreover, the work-up of the reaction is simpler since in an ideal case only the desired enantiomeric product is present in the reaction mixture. This concept is used for preparation of many important classes of organic compounds like natural and nonnatural a-amino acids, a-substituted nitriles and esters, cyanohydrins, 5-alkyl hydantoins, and thiazoUn-5-ones. 

Kanegafuchi Chemical Industries produce D-p-hydroxyphenyl glycine, which is a key raw material for the semisynthetic penicillins ampicillin and amoxycillin. Here, an enantioselective hydantoinase is applied to convert the hydantoin to the D-p-hydroxyphenyl glycine. The quantitative conversion of the amide hydrolysis is achieved because of the in situ racemization of the unreacted hydantoins. Under the conditions of enzymatic hydrolysis, the starting material readily racemizes. Therefore, this process enables the stereospecific preparation of various amino acids at a conversion of 100% [38]. 

Finally, another related study from the Sun laboratory concerned the synthesis of hydantoins utilizing acryloyl chloride to prepare a suitable polymer support [87]. All steps were carried out under reflux conditions in a dedicated microwave instrument utilizing 50-mL round-bottomed flasks. Identical reactions under classical thermal heating did not proceed in the same time period. 

Achiral hydantoin- and isoxazoline-substituted dispirocyclobutanoids 394 have been prepared by solid-phase synthesis (437). The facial and selective Boc-NH-mediated H-bond delivery of nitrile oxides afford dispirocyclobutanoids 394 (R = Bz, Et R1 =Ph, PI1CH2, Bu) as major compounds. 

Several syntheses of l,3-dioxoperhydropyrrolo[l,2-c]imidazoles have been developed using different strategies. a-Substituted bicyclic proline hydantoins were prepared by alkylation of aldimines 135 of resin-bound amino acids with a,tu-dihaloalkanes and intramolecular displacement of the halide to generate cr-substituted prolines 136 and homologs (Scheme 18). After formation of resin-bound ureas 137 by reaction of these sterically hindered secondary amines with isocyanates, base-catalyzed cyclization/cleavage yielded the desired hydantoin products <2005TL3131>. 

The method described serves for the preparation of various 5-substituted or 5,5-disubstituted hydantoins, using appropriate cyanohydrins. With methylethylketone cyanohydrin there was obtained a 75 per cent yield of 5-methyl-5-ethylhydantoin, m.p. i4i-5°-... 

Hydantoins with one or two substituents in the 5-position have been prepared by heating cyanohydrins with urea and treating... 

Hydantoin analogs in this series 72) were prepared. Most of these compounds, however, were found less active as anticonvulsants than the corresponding phenyl derivatives. Only a few were found to have the same order of activity as 5,5-diphenylhydantoin. 

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