Chiral azides

The alkyl azide 118 is reduced to a primary amine by the Pd on carbon-catalyzed reaction of ammonium formate in MeOH at room temperature. No racemization takes place with chiral azides[l 11,112]. 

Aliphatische und aromatische Azide werden durch 1,2-1,5 Mol-Aquivalente Lithiumalanat in siedendem Diathylather zu prim. Aminen reduziert8, chirale Azide werden nicht racemisiert9. 

When this strategy was applied to the chiral azide 343, a severe loss of optical activity occurred, but the synthetic sequence was continued to afford the target molecule 347 in almost racemic form (66) (Scheme 9.66). 

Reductive methylation Azides are converted to methylamines by Me BBr (8 examples, 63-99%). The stereointegrity of chiral azides is retained. 

A New Chiral and H-NMR Tagging Reagent for ee Analysis of Chiral Azides... 

We found that the C3 chiral pro-azaphosphatrane li is an excellent tagging agent for the direct determination of enantiomeric excesses of chiral azides using both P- and H-NMR spectroscopy [121]. Thus the reaction in Eq. (13) is carried out in an NMR tube at 50 °C for 2 hours, followed by NMR spectroscopic analysis. The excellent separations of the P-NMR chemical shifts (ca 1 ppm) allowed the ratios of the diastereomeric imidophosphorane derivatives to be easily measured and these ratios were very close to the expected values for commercially purchased racemic and chirally pure compounds as well as various mixtures of two enantiomers. These ratios were also in good agreement with those measured by H-NMR spectroscopic integration of the proton shifts in the tagged product [see Eq. (13)]. 

Scheme 15.11 Further transformation of the chiral azides. FIj (1 atm)7Pd7BaS04 (10mol%), 1-bromo-4-ethynylbenzene (1.2equiv), CuSO (20mol%), tris[(1-benzyl-1 H-1,2,3-triazol-4-yl)methyl]amine. The absolute configuration was determined by X-ray structure analysis [36].

A chiral azide functionalized ferrocenophane (Figure 12.5) was generated by Erker et al as a racemate by treating the corresponding lithiated ferrocenophane with tosyl azide and sodium pyrophosphate. In principle such compounds can be synthesized in an enan-tiomerically pure form, which would allow to obtain valuable intermediates for chiral ligands. 

Secondary amines having one oi two chiral groups attached to the nitrogen atom are prepared from boronic esters by their conversion into alkyldichlotobotanes, followed by treatment with organic azides (518). The second chiral group can be derived from an optically active azide. 

The major application of the Mitsunobu reaction is the conversion of a chiral secondary alcohol 1 into an ester 3 with concomitant inversion of configuration at the secondary carbon center. In a second step the ester can be hydrolyzed to yield the inverted alcohol 4, which is enantiomeric to 1. By using appropriate nucleophiles, alcohols can be converted to other classes of compounds—e.g. azides, amines or ethers. 

Intermolecular Schmidt reactions of alkyl azides and hydroxyalkyl azides with cycloketones in the presence of a Lewis acid, lead to formation of iV-alkyl lactams and A-hydroxyalkyl lactams respectively in good yield. The synthesis of chiral lactams by an asymmetric Schmidt reaction has also been reported. ... 

While it was felt that some of the individual issues above could be addressed using the same synthetic sequence (e.g., alternate catalysts for the reduction step) it seemed unlikely that all the above would be solvable, especially as efforts to replace sodium azide with other nucleophiles had failed. Based on this assessment the team felt it would be necessary to evaluate a fundamentally new approach to taranabant and, in particular, to look for a method for installation of the chiral centers without the intermediacy of an alcohol. 

Tandem azidination- and hydroazidination-Hiiisgen [3 +2] cycloadditions of ynamides are regioselective and chemoselective, leading to the synthesis of chiral amide-substituted 1,2,3-triazoles <06OBC2679>. A series of diversely l-substituted-4-amino-l,2,3-triazoles 132 were synthesized by the copper-catalyzed [3+2] cycloaddition between azides 130 and ynamides 131 <06T3837>. 

A variety of triazole-based monophosphines (ClickPhos) 141 have been prepared via efficient 1,3-dipolar cycloaddition of readily available azides and acetylenes and their palladium complexes provided excellent yields in the amination reactions and Suzuki-Miyaura coupling reactions of unactivated aryl chlorides <06JOC3928>. A novel P,N-type ligand family (ClickPhine) is easily accessible using the Cu(I)-catalyzed azide-alkyne cycloaddition reaction and was tested in palladium-catalyzed allylic alkylation reactions <06OL3227>. Novel chiral ligands, (S)-(+)-l-substituted aryl-4-(l-phenyl) ethylformamido-5-amino-1,2,3-triazoles 142,... 

A rather complex microwave-assisted ring-opening of chiral difluorinated epoxy-cyclooctenones has been studied by Percy and coworkers (Scheme 6.131) [265]. The epoxide resisted conventional hydrolysis, but reacted smoothly in basic aqueous media (ammonia or N-methylimidazole) under microwave irradiation at 100 °C for 10 min to afford unique hemiacetals and hemiaminals in good yields. Other nitrogen nucleophiles, such as sodium azide or imidazole, failed to trigger the reaction. The reaction with sodium hydroxide led to much poorer conversion of the starting material. 

The synthesis of the rare amino acid 3-hydroxy-4-methylproline (8)3 involves an aldol reaction of the oxazoiidinone 5 with methacrolein to provide the a-bromo-0-hydroxy adduct 6. Azide displacement and removal of the chiral auxiliary gives 7. On treatment with dicyclohexylborane, 7 undergoes hydroboration-cycloalkyl-ation to provide, after hydrolysis, the methyl ester hydrochloride (8) of (2S,3S,4S)-3-hydroxy-4-methylproline in >97% de. This cycloalkylation should be a useful route to cyclic amino acids as well as pyrrolidines. 

Azidation.1 Arylsulfonyl azides generally react with enolates to effect net diazo transfer, but this hindered and electron-rich azide can effect azide transfer at the expense of diazo transfer. The nature of the enolate counterion also plays a role, with K being more effective than Na. In addition, acetic acid (or KOAc) is required as the quench for decomposition of the triazine intermediate to the azide with elimination of the arylsulfinic acid, ArS(0)0H. By use of these conditions, chiral N-acyloxazolidones such as 2 undergo diastereoselective azidation to give the azides 3 in 75-90% yield and in high optical purity (>91 9). These... 

Acyl azides (see Section 2.13) The acyl-azide method of coupling is unique for two reasons. First, it is the only case in which the immediate precursor of the activated form of the peptide is not the parent acid. The starting material is the peptide ester that is obtained from the amino acid ester by usual chain assembly (Figure 2.25, path A). Second, it is the only method that just about guarantees production of a peptide that is enantiomerically pure, provided scrupulous attention is paid to details of procedure. There is no danger for loss of chirality during conversion of the ester to the hydrazide and then the azide, but care must be taken to avoid contact of... 

Asymmetric introduction of azide to the a-position of a carbonyl has been achieved by several methods. These include amine to azide conversion by diazo transfer,2 chiral enolate azidation,3 and displacement of optically active trifluoromethanesulfonates,4 p-nitrobenzenesulfonates,5 or halides.6 Alkyl 2-azidopropionates have been prepared in optically active form by diazo transfer,2 p-nitrobenzenesulfonate displacement,5 and the Mitsunobu displacement using zinc azide.7 The method presented here is the simplest of the displacement methods since alcohol activation and displacement steps occur in the same operation. In cases where the a-hydroxy esters are available, this would be the simplest method to introduce azide. 

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