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Optically active chiral amines, synthesis

Catalytic enantioselective Mannich reactions provide one of the most versatile approaches for the synthesis of optically active chiral amines. Recently, several organocatalytic protocols have been developed using the parent cinchona alkaloids or their derivatives. [Pg.209]

The synthesis of optically active compounds by the diastereoselective reaction of allyltitanium reagents with chiral electrophiles has also been reported. The reaction of allyltitanium reagents with chiral imines proceeds with excellent diastereoselectivity, as shown in Eq. 9.28, thus providing a new method for synthesizing optically active homoallylic amines with or without a P-substituent [51,52],... [Pg.334]

Many other uses of a-sulfinyl carbanions are found in the literature, and in the recent past the trend has been to take advantage of the chirality of the sulfoxide group in asymmetric synthesis. Various ways of preparation of enantiopure sulfoxides have been devised (see Section 2.6.2) the carbanions derived from these compounds were added to carbonyl compounds, nitriles, imines or Michael acceptors to yield, ultimately, with high e.e. values, optically active alcohols, amines, ethers, epoxides, lactones, after elimination at an appropriate stage of the sulfoxide group. Such an elimination could be achieved by pyrolysis, Raney nickel or nickel boride desulfurization, reduction, or displacement of the C-S bond, as in the lactone synthesis reported by Casey [388]. [Pg.176]

Vinyl epoxides can also be used as substrates for formation of optically active allyl amines catalyzed by the same type of chiral palladium complexes as in Eq. (10). By reaction of simple vinyl epoxides with phthalimide as the nitrogen source in the presence of the chiral palladium complexes as the catalyst, very high ee (> 98 %) and regioselectivity (> 97 %) were obtained [26]. A variety of different applications of the use of the palladium-catalyzed approach for the formation of allyl amines and the use of this in total synthesis has been pursued by several research groups, and further details can be obtained in a review by Trost et al. [19d]. [Pg.13]

The acetoxy group was hydrolyzed using hydrazine to give (46). Nucleophilic substitution of the fluorine atom produced the tricyclic /3 lactam (47). A diastereoselective aza-Diels-Alder reaction was used in a synthesis of (-)-lasubine (I). Tin tetrachloride mediated reaction of complex (48) with Danishefsky s diene afford 2,3-dihydro-4-pyridone (49) as a single diastereomer (Scheme 86). Chiral benzaldehyde imines can be aUylated with high diastereoselectivity to give optically active homoaUyhc amines (Scheme 87). [Pg.3236]

The enantioselective [2,3]sigmatropic rearrangement of allylic selenimides has been achieved by application of the asymmetric synthesis of selenimides [35]. When this reaction was applied to various aryl cinnamyl selenides, the expected optically active allylic amines were obtained in good yield with moderate enan-tioselectivity via [2,3]sigmatropic rearrangement of the intermediate chiral allylic selenimides (Scheme 25). [Pg.224]

The enantioselective synthesis of optically active secondary amines via asymmetric reduction of prochiral ketimines was studied by screening various chiral hydrides. In this case, K-glucoride gave only disappointing results and was inferior to other reagents. Better results were obtained in the asymmetric reduction of prochiral Af-diphenylphosphinylimines to chiral N-(diphenylphosphinyl)amines (eq 1), which can then be readily converted into optically active primary amines. For this reaction the stereochemical course depends dramatically on the relative bulkiness of the groups R and R. The reaction conditions for reduction of C=N double bonds are the same as used for ketones, but the high reactivity of diphenylphosphinylimines dramatically reduces the reaction time. [Pg.237]

Opine-type secondary amine dicarboxylic acids are useful chiral intermediates of angiotensin-converting enzyme (ACE)-inhibitors, such as enalapril and lysinopril. In order to extend the use of enzymes in stereoselective synthesis, we screened for an enzyme catalyzing the reversible oxidation-reduction of opine-type secondary amine dicarboxylic acids and isolated a bacterial producer, Arthrobacter sp. strain 1C [15]. Optically active secondary amine dicarboxylic acids have been chemically synthesized as... [Pg.21]

Synthesis.—Mannich-type Reactions. The double Michael addition of amines to cyclohepta-2,6-dienone has been extended by the use of a series of optically active primary amines to the synthesis of chiral 8-azabicyclo-[3,2,l]octanes. Yields are typically ca. 70% circular dichroism studies show interesting effects. Perturbation of the n - rr transition must originate in the asymmetry of the nitrogen substituents which lie in the symmetry plane of the ring. The analysis of the tertiary amines is complicated by... [Pg.355]

A synthesis of optically active citroneUal uses myrcene (7), which is produced from P-piaene. Reaction of diethylamine with myrcene gives A/,A/-diethylgeranyl- and nerylamines. Treatment of the aHyUc amines with a homogeneous chiral rhodium catalyst causes isomerization and also induces asymmetry to give the chiral enamines, which can be readily hydrolyzed to (+)-citroneUal (151). [Pg.423]

In Ugi four-component reactions (for mechanism, see Section 1.4.4.1.) all four components may potentially serve as the stereodifferentiating tool65. However, neither the isocyanide component nor the carboxylic acid have pronounced effects on the overall stereodiscrimination60 66. As a consequence, the factors influencing the stereochemical course of Ugi reactions arc similar to those in Strecker syntheses. The use of chiral aldehydes is commonly found in substrate-controlled syntheses whereas the asymmetric synthesis of new enantiomerically pure compounds via Ugi s method is restricted to the application of optically active amines as the chiral auxiliary group. [Pg.795]

The exchange of the chiral phenylethyl amine against an optically active amino acid fragment 269 allowed the synthesis of conformationally restrained dipeptidyl lactams 271 and 272 including the so called Freidinger lactams as... [Pg.168]

As 29 had been recognized as the most accessible starting-material for the synthesis of racemic carba-sugars, its resolution was successfully achieved with optically active a-methylbenzylamine as chiral reagent. Reaction of 29 with (-l-)-a-methylbenzylamine gave a mixture of two diastereoisomeric salts [(+)-amine, (—)-29 and (+)-amine, (-l-)-29], which were well separated, and the former salt was converted into (—)-29, [a] -111.8° (ethanol). Analogously, (+)-29, [a] +110.7° (ethanol), was obtained. ... [Pg.36]

Mikolajczyk and coworkers have summarized other methods which lead to the desired sulfmate esters These are asymmetric oxidation of sulfenamides, kinetic resolution of racemic sulfmates in transesterification with chiral alcohols, kinetic resolution of racemic sulfinates upon treatment with chiral Grignard reagents, optical resolution via cyclodextrin complexes, and esterification of sulfinyl chlorides with chiral alcohols in the presence of optically active amines. None of these methods is very satisfactory since the esters produced are of low enantiomeric purity. However, the reaction of dialkyl sulfites (33) with t-butylmagnesium chloride in the presence of quinine gave the corresponding methyl, ethyl, n-propyl, isopropyl and n-butyl 2,2-dimethylpropane-l-yl sulfinates (34) of 43 to 73% enantiomeric purity in 50 to 84% yield. This made available sulfinate esters for the synthesis of t-butyl sulfoxides (35). [Pg.63]

Scheme 26 Synthesis of optically active amines 91 using the chiral amination reagent 89... Scheme 26 Synthesis of optically active amines 91 using the chiral amination reagent 89...
In contrast to the success in the synthesis of optically active amino acids and related compounds, only limited success has been achieved in the asymmetric synthesis of chiral amines or related compounds. One breakthrough is the asymmetric hydrogenation of arylenamides with Rh catalysts containing... [Pg.349]

Amination. Three laboratories2-4 have reported use of esters of azodicarbox-ylic acid for amination of chiral substrates to provide a synthesis of optically active a-hydrazino and a-amino acids. The di-r-butyl ester is particularly useful because the diastereoselectivity improves with increasing size of the ester group, and in addition these esters are hydrolyzed by TFA at 25°. Two laboratories21 used the lithium enolates of chiral N-acyloxazolidones (2) as the chiral precursors. A typical procedure is outlined in equation (I). Thus reaction of the lithium enolate of 2... [Pg.115]

Chiral amines.1 These reagents also add to imines and this reaction can be used for synthesis of optically active amines. Thus RCeCl2 adds to SAMP-hydra-zones (12, 30) to form hydrazines in good yield and high diastereoselectivity. These are reduced to optically active amines by hydrogenation catalyzed by Raney nickel. The hydrazines are prone to oxidation, but can be isolated as the stable carbamates. [Pg.217]

Based on nucleophilic addition, racemic allenyl sulfones were partially resolved by reaction with a deficiency of optically active primary or secondary amines [243]. The reversible nucleophilic addition of tertiary amines or phosphanes to acceptor-substituted allenes can lead to the inversion of the configuration of chiral allenes. For example, an optically active diester 177 with achiral groups R can undergo a racemization (Scheme 7.29). A 4 5 mixture of (M)- and (P)-177 with R = (-)-l-menthyl, obtained through synthesis of the allene from dimenthyl 1,3-acetonedicar-boxylate (cf. Scheme 7.18) [159], furnishes (M)-177 in high diastereomeric purity in 90% yield after repeated crystallization from pentane in the presence of catalytic amounts of triethylamine [158], Another example of a highly elegant epimerization of an optically active allene based on reversible nucleophilic addition was published by Marshall and Liao, who were successful in the transformation 179 — 180 [35], Recently, Lu et al. published a very informative review on the reactions of electron-deficient allenes under phosphane catalysis [244]. [Pg.383]

An analogous reaction is the conversion of olefins into primary amines by the consecutive action of BH3. THF and trimethylsilyl azide171. The observation172 that organoboranes and chloramine give primary amines is the basis of an amine synthesis in which olefins are treated with the complex BH3 THF, followed by aqueous ammonia and aqueous sodium hypochlorite173. Imines are reduced by the chiral dioxaborolidine 162 to yield optically active amines. 1-Imino-l-phenylpropane, for instance, affords 1-phenylpropylamine in 73% enantiomeric excess (equation 59)174. [Pg.565]

It is worth mentioning that the extent of asymmetric induction in the sulfinate synthesis is comparable with that observed in the reaction of sulfinyl chlorides with optically active alcohols. However, in this case, the sulfinate products contain only one chiral center on sulfur the chiral-inducing amine is very easily recovered as the hydrochloride. [Pg.354]

The original synthesis of duloxetine (3) is relatively straightforward, involving a four-step sequence from readily available 2-acetylthiophene 30 (Scheme 14.7). Understandably, the main synthetic challenge stems from the presence of a chiral center, because duloxetine (3) is marketed as the (5)-enantiomer as shown. Thus, a Mannich reaction between 30 and dimethylamine generated ketone amine 31, which was then reduced to provide intermediate racemic alcohol amine 32. The desired optically active (5)-alcohol 32a was accessed via resolution of racemate 32 with (5)-(+)-mandelic acid, which provided the necessary substrate for etherihcation with 1-fluoronaphthalene to afford optically active amine 33. Finally, A -demethylation with 2,2,2-trichloroethyl chloroformate and cleavage of the intermediate carbamate with zinc powder and formic acid led to the desired target duloxetine (3). [Pg.207]

When an aldehyde is allowed to react with an optically active amine and hydrocyanic acid, one of the two diastereomeric amino nitriles, (124a) or (124b), may be formed in excess. To prepare the chiral amino acids (125a) or (125b), the nitriles (124a) and (124b), respectively, are hydrolyzed with mineral acids, whereupon R is split off. However, this asymmetric synthesis of amino acids has no industrial significance. [Pg.200]

A chiral recognition was observed in aminolysis of 3-acyl-4(R)-methoxycarbonyl-l,3-thiazolidine-2-thione, a derivative of (R)-cysteine, by racemic amines to give an optically active amide [(S)-excess] and amine [(R)-excess]264). In the reaction of cyclic meso-1,3-diols with chiral N-protected phenylalanyl chlorides, Yamada et al.26S) observed the preferential formation of one of the two possible diastereomeric monoesters, which has been used for the synthesis of optically active steroids 266) and prostaglandins 267). [Pg.234]


See other pages where Optically active chiral amines, synthesis is mentioned: [Pg.482]    [Pg.222]    [Pg.104]    [Pg.222]    [Pg.25]    [Pg.67]    [Pg.201]    [Pg.63]    [Pg.175]    [Pg.4]    [Pg.165]    [Pg.265]    [Pg.307]    [Pg.562]    [Pg.13]    [Pg.73]    [Pg.65]    [Pg.249]    [Pg.239]    [Pg.85]    [Pg.463]    [Pg.167]   
See also in sourсe #XX -- [ Pg.209 ]




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Activators amines

Amines activation

Amines chirality

Amines optically active

Amines synthesis

Chiral activator

Chiral activity

Chiral aminals

Chiral amines

Chiral amines synthesis

Chiral synthesis

Optical amines

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