Phosphites silyl groups

Nucleophilic phosphonylations of w-silyloxy aldehydes (e.g. 77) with phosphite 78 give a mixture of 79 and 80 with moderate to good diastereoselectivity (equation 36)55. The ratio of 79/80 depends greatly upon the size of the silyl groups in 77, according to the order shown in entry 42 of Table 1. 

By contrast, reactions with silyl phosphites do not give the phosphazenes (26), for the silyl group readily migrates to nitrogen, leaving (27). The same tendency for migration of the silyl group has also been noted for intermediates derived from azides. ... 

The triethylsilyl ether 147 thus formed regiospecifically from the diol 150 [Rl=(BnO)2 (0), R2=Bn], which was optically resolved by a chiral column chromatography, was transformed to Ins(2,4,5)P3 and Ins(l,4,5)P3 (Schema 3-23). At this stage, temporary protection of OH-1 with the silyl group is not necessary, i.e. 150 can be directly phosphorylated by the phosphite-phosphonium approach as described in the section on phosphorylation (Scheme 2-6). H The diol 150 was used furthermore as a versatile synthetic intermediate for the synthesis of myo-inositol 1,2-cyclic-4,5-trisphosphate 152 (Scheme 3-23), 8 2-acyl analogues of Ins(1,4,5)P3, and inositol phospholipid. 

Scheme 2.96 Silyl groups as leaving groups in phosphite synthesis.

Me3Si)2NH, Me3SiCl, Pyr, 20°, 5 min, 100% yield. ROH is a carbohydrate. Hexamethyldisilazane (HMDS) is one of the most common sily-lating agents and readily silylates alcohols, acids, amines, thiols, phenols, hydroxamic acids, amides, thioamides, sulfonamides, phosphoric amides, phosphites, hydrazines, and enolizable ketones. It works best in the presence of a catalyst such as X-NH-Y, where at least one of the group X or Y is electron-withdrawing. ... 

In this context, it is interesting to note that the first synthesis of 2, 3 -0,0-cyclic phosphorothioate 22a was reported by Eckstein in 1968 [25], He also isolated pure Rp diastereomer by fractional crystallization of the triethylammonium salts [26] and used it as reference to determine the absolute configurations of the other phosphorothioate analogues [27], 2, 3 -0,0-Cyclic H-phosphonate 20a was used as a key substrate for the synthesis of uridine 2, 3 -0,0-cyclic boranophosphate 27. Silylation of H-phosphate 20a gave the phosphite triester 25 (two diastereomers). Its boronation, with simultaneous removal of the trimethylsilyl group, was achieved by its reaction with borane-A.A-diisopropylethylamine complex (DIPEA-BH3). 

Sekine, M., Mori, H., and Hata, T., Protection of phosphonate function by means of ethoxycarbonyl group. A new method for generation of reactive silyl phosphite intermediates, Bull. Chem. Soc. Jpn., 55, 239, 1982. 

The phosphitylation procedure activated by tetrazole led to the phosphite structure (step a) which was effectively oxidized by TBHP to yield the corresponding phosphate (step b). Finally all 2-cyanoethyl protecting group were removed by the action of DBU in the presence of the silylating reagent bis(trimethylsilyl)acetamide BSA (step c). The latter is indispensable to secure total deprotection. 

When using mixed phosphites, some useful regioselectivity is possible in the dealkylation step, thus benzyl is lost in preference to alkyl groups, for example, from dibenzyl methyl phosphite,19 and silyl in preference to alkyl groups (see below). 

The 2-(methyldiphenylsilyl)ethyl (DPSME) group was used to protect a phosphate in a synthesis of Lysobisphosphatidic Acid [Scheme 7.40].82 The phosphate protection was introduced by a phosphite triester approach to give the symmetrical phosphate 40 2. The two isopropylidene groups were removed by acid hydrolysis without harm to the phosphate and the resultant diols selectively protected on their less hindered termini with fert-butyldiphenylsilyl groups. Acylation of the remaining secondary hydroxyls with oleic anhydride afforded the diester 403, whereupon the silyl protecting groups were removed with... 

Attack on Nitrogen. A new route to phosphoramidates, involving the reaction of silyl phosphites with the appropriate azide, followed by hydrolysis, has been developed. The mechanism (see Scheme 6) probably involves initial formation of the phosphite imine (36) followed by migration of a sUyl group from oxygen to nitrogen, and it is exemplified by the synthesis of the oligoazanucleotide (37). 

D. The calculations confirm that the negative end of the dipole is towards phosphorus. - The calculated dipole moments of phosphole (1.9 D) and pyrrole (2.0 D) are similar, and, unlike furan, the positive ends of the dipoles are towards the heteroatoms. Dipole moments have been used, in combination with results from other methods of study, to estimate the preferred conformations of the dichloride (179), of the phosphites (180), and of triarylphosphine oxides. The use of dipole moments to aid stereochemical studies of compounds has been reviewed. Additive polarizability parameters should not be used in the calculations, and it has been recommended that data should be obtained from model compounds containing identical environments for the phosphorus atoms. The sensitivity of bond moments to structural changes has been studied perfluoroalkyl groups lower the phosphoryl bond moment, and the P—N bond moment is very sensitive to the valence state of the phosphorus atom. The conformational analyses of phospho-nates, phosphonamides, silyl phosphates, and a number of dioxaphosphori-nans (181) - have been reported. The P—Se bond moment has been estimated to be 1.24 D. The zwitterionic structure (182) was identified by its high dipole... 

Recently, it has been shown that nucleophilic addition of neat dimethyl trimethylsilyl phosphite to serine-derived P-lactonc at I ()() C for 24 h leads specifically to the carboxylic trimethylsilyl ester by preferential transfer of the trimethylsilyl group. A simple aqueous workup induces hydrolysis of the silyl ester to give the N- and P-protected free carboxylic acid ready for activation and coupling. 

The ethoxycarbonyl group was developed for the protection of phosphonates. The derivative is prepared by reaction of tris(trimethylsilyl) phosphite with ethyl chlo-roformate and can be cleaved by hydrolysis of the ester followed by silylation with bistrimethylsilylacetamide. ... 

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