Chiral compounds amination

Reaction of 2-[A -(rra -crotyl)-A -benzylamino]-3-formyl-4/f-pyrido[l,2-n]pyrimidin-4-one (269) with chiral primary amines 270 and 271 gave mixtures of diastereoisomers of tetracyclic compounds 273 and tricyclic 275 (96T131]]). The chiral centers in 272 and 274 did not provide any stereocontrol for the formation of diastereomers 273 and 275, respectively. 

A closely related method does not require conversion of enantiomers to diastereomers but relies on the fact that (in principle, at least) enantiomers have different NMR spectra in a chiral solvent, or when mixed with a chiral molecule (in which case transient diastereomeric species may form). In such cases, the peaks may be separated enough to permit the proportions of enantiomers to be determined from their intensities. Another variation, which gives better results in many cases, is to use an achiral solvent but with the addition of a chiral lanthanide shift reagent such as tris[3-trifiuoroacetyl-Lanthanide shift reagents have the property of spreading NMR peaks of compounds with which they can form coordination compounds, for examples, alcohols, carbonyl compounds, amines, and so on. Chiral lanthanide shift reagents shift the peaks of the two enantiomers of many such compounds to different extents. 

Dienes with Chiral Auxiliaries The use of dienes with the chiral auxiliary attached to the C-l position of the dienes is the most popular in asymmetric Diels-Alder reactions.59 In 1980, Trost reported high asymmetric induction in the Diels-Alder reaction using l-(S)-0-methylmandeloxy-l,4-butadiene59a However, the result obtained by Trost et al. has remained unique for more than a decade, at least in terms of enantioselectivity. The asymmetric Diels-Alder reaction of chiral diene-amines with nitroalkenes gives aminocyclohexenes with good diastereoselectivity (Eq. 8.37).60 The development in the area of chiral dienes is slow it may be due to the difficulty of preparing these compounds. 

Sulfoximines are an example of a tetracoordinated chiral compound, and their optical isomers have been isolated. Their stereochemistry was also studied approximately 30 years ago.43 Endocyclic sulfoximines are an example of chiral heteroaromatics. Endocyclic sulfoximines 26 were optically resolved on a chiral column for the first time by Allenmark and co-workers in 1995.44 The stereoisomers were obtained by amination and subsequent cyclodehydration of optically active o-carboxyphenyl sulfoxide with hydrazoic acid or 0-(me-sitylenesulfonyl) hydroxylamine (Scheme 14). 

Cyclic amines (including local anesthetic drugs) and amides were among the first classes of chiral compounds investigated in the early stages of the application of macrocyclic antibiotics as chiral selectors therefore, they were screened on vancomycin [7], teicoplanin [30], and ristocetin A [33] CSPs, under RPmode systems. Cyclic imides (including barbiturates, piperidine-2,6-diones, and mephenytoin) have been separated on a vancomycin CSP [157], under NP and RP mobile phase conditions. 

The first assignment of the chirality (absolute configuration) to a planar chiral phane ([2.2]paracyclophanecarboxylic acid 23, in 1968),04) was deduced from the results of a kinetic resolution of its (racemic) anhydride with (—)-l-phenylethyl-amine and is based on the related topology of 23 and 2-methyl-metallocene-l-carb-oxylic acids 19). For these chiral compounds, this method had given (correct) results, as confirmed afterwards by the Bijvoet method 109). Since this method has been reviewed in some detail19,100) it will not be discussed in this survey. 

The alkylation of caclohexanone has been studied as a model reaction in detail. Generally, enamino compounds (126) are allowed to react with alkyl halides or a, 3-unsaturated carbonyl compounds. The enamine (126a) is prepared directly from the ketone and a chiral secondary amine (route A). A metalloenamine (126b) can be synthesized from chiral azomethine, derived from the model ketone and a primary chiral amine (route B). The primary amine used for the formation of (126b) must possess an oxygen function. This oxygen function plays a key role in the coordination of the lithium ion in the complex (126b). 

Nevertheless, chiral propargylic amines remain interesting substrates for achieving the diastereoselective addition of substituted allylic organozinc compounds to metallated alkynes. Besides crotylzincation, one example of diastereoselective addition of zincated allyl ethyl ether to 328 has also been reported183. 

P. Newman, Optical Resolution Procedures for Chiral Compounds, vol. 1, Amines and Related Compounds , Optical Resolution Information Center, Manhattan College, Riverdale, NY, 1978. 

Careful inspection of the reported photocatalytic reactions may demonstrate that reaction products can not be classified, in many cases, into the two above categories, oxidation and reduction of starting materials. For example, photoirradiation onto an aqueous suspension of platinum-loaded Ti02 converts primary alkylamines into secondary amines and ammonia, both of which are not redox products.34) ln.a similar manner, cyclic secondary amines, e.g., piperidine, are produced from a,co-diamines.34) Along this line, trials of synthesis of cyclic imino acids such as proline or pipecolinic acid (PCA) from a-amino acids, ornithine or lysine (Lys), have beer. successfuL35) Since optically pure L-isomer of a-amino acids are available in low cost, their conversion into optically active products is one of the most important and practical chemical routes for the synthesis of chiral compounds. It should be noted that l- and racemic PCA s are obtained from L-Lys by Ti02 and CdS photocatalyst, respectively. This will be discussed later in relation to the reaction mechanism. 

Trimethylindolenine was hydrogenated with a catalyst consisting of [IrCl(COD)]2, (R,R)-BICP, and phthalimide in CH2C12 under 68 atm of H2 to afford the chiral cyclic amine in 95.1% ee (Scheme 9) [20]. The addition of phthalimide remarkably increased the optical yield [21]. Hydrogenation of a dihydroisoquinoline compound with a neutral (R)-BINAP/Ir complex in... 

Reductive amination reactions of keto acids are performed with amino acid dehydrogenases. NAD-dependent leucine dehydrogenase from Bacillus sp. is of interest for the synthesis of (S)-fert.-leucine [15-17]]. This chiral compound has found widespread application in asymmetric synthesis and as a building block of biologically active substances. The enzyme can also be used for the chemoenzy-matic preparation of (S)-hydroxy-valine [18] and unnatural hydrophobic bran-ched-chain (S)-amino acids. NAD-dependent L-phenylalanine dehydrogenase from Rhodococcus sp. [19] has been used for the synthesis of L-homophenyl-alanine ((S)-2-Amino-4-phenylbutanoic acid) [9]. These processes with water-soluble substrates and products demonstrate that the use of coenzymes must not... 

It has been found that the results of this new variant of the Mitsunobu procedure are generally comparable with the results of the traditional Mitsunobu reaction both with respect to the yields and enantiomeric excess (ee) of chiral compounds 26. Thus, products prepared from alcohol 86e using both methods had ee 70% and 72%, and from (Tl-methyl lactate 86i 92% and 99%, respectively. However the new variant of the Mitsunobu procedure has a significant synthetic advantage over the traditional procedure imides 26 can be transformed into primary amines under milder conditions in comparison with the deprotection of /V-alkylphthalimides (see Section 6.03.6.1.3). 

Natural products having chiral tertiary amine functions were tested among the first catalysts in asymmetric MBH reactions [24, 60]. The importance of the proton donor capacity of the catalyst in the rate and selectivity of the MBH reaction was recognized very quickly, and attention was turned to genuine a-amino alcohol structures, such as the compounds listed in Scheme 5.8 [61]. Results were modest, however. Apart from the earlier discussed (R)-3-HDQ, which catalyzed the MBH reaction at atmospheric pressure (though with no enantioselectivity),... 

Ohashi and co-workers have carried out a systematic study of derivatives of 41 (Scheme 26) to determine factors which allow racemization of some compounds but not others. For example, they find that for R = (R) or (S) methylbenzyl-amine or R = pyrrole, racemizations occur with a rate constant of about 1.5-3.0 x 10-6 s 1. For other compounds (with R = triphenylphosphine, tributylphosphine, diphenylethylphosphine, and diethylphenylphosphine) no reaction was observed at room temperature. The reactivity (or lack thereof) correlates well with the cavity volume accessible to the reacting group [123], For compounds that crystallize with two molecules per unit cell the effect of cooperative racemization can be observed and can also be related to cavity size [124-126]. Possibilities available to reactive chiral compounds have been classified by Ohashi as follows [120]. 

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