Amine oxides phosphoramidates

The excellent enantioselectivity and wide scope of the CBS reduction have motivated researchers to make new chiral auxiliaries [3]. Figure 1 depicts examples of in situ prepared and preformed catalyst systems reported since 1997. Most of these amino-alcohol-derived catalysts were used for the reduction of a-halogenated ketones and/or for the double reduction of diketones [16-28]. Sulfonamides [29,30], phosphinamides [31], phosphoramides [32], and amine oxides [33] derived from chiral amino alcohols were also applied. The reduction of aromatic ketones with a chiral 1,2-diamine [34] and an a-hydroxythiol [35] gave good optical yields. Acetophenone was reduced with borane-THF in the presence of a chiral phosphoramidite with an optical yield of 96% [36]. 

Several approaches to the 1,2,3-triazole core have been published in 2000. Iodobenzene diacetate-mediated oxidation of hydrazones 152 led to fused 1,2,3-triazoloheterocycles 153 <00SC417>. Treatment of oxazolone 154 with iso-pentyl nitrite in the presence of acetic acid gave 1,2,3-triazole 155, a precursor to 3-(W-l,2,3-triazolyl)-substituted a,P-unsaturated a amino acid derivatives <00SC2863>. Aroyl-substituted ketene aminals 156 reacted with aryl azides to provide polysubstituted 1,23-triazoles 157 <00HC387>. 2-Aryl-2T/,4/f-imidazo[43-d][l,2,3]triazoles 159 were prepared from the reaction of triethyl AM-ethyl-2-methyl-4-nitro-l//-imidazol-5-yl phosphoramidate (158) with aryl isocyanates <00TL9889>. 

Cyclophosphamide (6.31) is a nitrogen mustard used for cancer treatment (Scheme 6.9). In the body, cyclophosphamide is oxidized to aminal 6.32. Compound 6.32 opens and loses acrolein to form phosphoramide mustard (6.33). Structure 6.33 is a strong bis-electrophile and reacts readily with nucleophiles. In DNA, the nucleophile tends to be N7 of guanine, which is oriented outward into the major groove (Figure 6.6). By reacting twice, 6.33 crosslinks DNA either within the same strand (intrastrand) or across the double helix (interstrand).16... 

Symmetrical dinucleoside phosphoramidates and iV-substituted phosphora-midates (63) and (64) were obtained after oxidative coupling of the symmetrical //-phosphonate diester of AZT with the appropriate amine Biological evaluation on HIV-infected TK-deficient cell lines suggested that such dinucleoside phosphoramidates could not be regarded as pronucleotides, as they were unable to deliver the corresponding 5 -nucleotide inside the cells. 

Chiral phosphoramides, particularly C2-symmetric examples, are widely used in asymmetric synthesis (see section 3.2). One example is the asymmetric catalysis of Aldol reactions, where the phosphoramide catalyst is used in combination with a Lewis base. A solid state and solution study of the structure of chiral phosphoramide-tin complexes used in such reactions has now been reported. A number of chiral, non-racemic cyclic phosphoramide receptors (387) have been synthesised and their interactions with homochiral amines studied using electrospray ionisation MS. Although (387) bind the amines strongly, no evidence of chiral selectivity was found. Evidence from a combination of its X-ray structure, NMR, and ab initio calculations suggests that the cyclen phosphorus oxide (388) has an N-P transannular interaction in the solid state. A series of isomers of l,3,2-oxazaphosphorino[4,3-a]isoquinolines(389), containing a novel ring-system, have been prepared and their stereochemistry and conformation studied by H, C, and P NMR spectroscopy and X-ray crystallography... 

Suarez developed neutral conditions for the Hofmann-Ldffler-Freytag reaction using a similar approach to the hypoiodite reaction described in Section 3.6.2.2. In this procedure, A -iodoamides are generated in situ by reaction of the corresponding amine derivative with iodine in the presence of lead tetraacetate or DIB as oxidizing agent. Nitroamines (Z = NO2) [67], phosphoramidates [Z = PO(OR)2 and PO(OEt)2] [68] and cyanamides (Z = CN) [69] have been used (Scheme 13, Eq. 13.1). A typical example is presented in Eq. (13.2). 

The novel dinucleotide phosphoramidate (78) has been obtained from the phosphoramidite dimer (79) upon reaction with methoxymethylene ethanolamine in the presence of tetrazole, followed by iodine oxidation in the presence of the same amine. Since the two amino substituents are identical it is envisaged that in aqueous solution, rapid proton transfer between the two phosphoramido moieties will render the molecule achiral at phosphorus. 

Electrochemical oxidation and reduction of het-ero atom compounds, such as N, S, and P compounds, has been intensively studied and utilized for synthesis of many fine chemicals [1-4]. Electrooxidative S-S, S-N, S-P, and N-P bond formation is performed successfully by electrolysis of thiols, disulfide/amine, disulfide/phosphate, amine/ phosphate, and so on, affording useful chemicals, e.g., thiuram disulfide [17], sulfenamide [18], sulfenimides [19], phosphorothiolates [20], phosphoramidate [21], and so on. For instance, cross-coupling of phthalimide and dicyclohexy disulfide is performed by electrolysis in acetonitrile containing a catalytic amount of sodium bromide under a ccaistant apphed voltage (3 V, 0.7-0.9 V vs. SCE) to afford N-(cyclohexylthio)phthalimide, an important prevulcanization inhibitor in the rubber industry, in quantitative yield [19] (Fig. 4). 

Phosphoramidates are prepared in high yield by oxidation with CCI4 in the presence of a primary or secondary amine. This procedure has led to the successful synthesis of oligodeoxynucleotides with a high degree of substitution at phosphorus by phosphoramidates (7,10, 11,16). 

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