Silyloxy group

The product can be examined for purity by proton magnetic resonance or by gas chromatography. The submitters have used XF-1150 columns successfully. Columns with polar sites will strip silyloxy groups from the bis(silyloxy) compounds and are unsatisfactory. 

Node and co-workers have found that the Diels-Alder reaction of nitroalkenes v/ith 1-methoxy-3-trimethylsilyloxy-l,3-butadiene (Danishefsky s dienesi exhibit abnormal exo-se-lecdvity Electrostadc repulsion between the nitro and the silyloxy group of the diene induces this abnormal exc-selecdvity (Tq 8 10 This selecdve reacdon has been used for the asymmetric synthesis of various naniral products as shovm in Scheme 8 6... 

Insoluble chitin 2211 is readily silylated by HMDS 2 and Me3SiCl 14 to form the soluble, much more lipophilic 2212, whose 6-silyloxy groups can either be tri-tylated with PhsCCl or glycosylated with the peracetylated oxazolidine 2213, derived from D-glucosamine, in C1(CH2)2C1 in the presence of camphorsulfonic acid (CSA) to give, on work-up with methanol, the branched chitin 2214 in high yields [22] (Scheme 14.8). 

The potential for coordination depends on the oxy substituents.82 Alkoxy substituents are usually chelated, whereas highly hindered silyloxy groups usually do not chelate. Trimethylsiloxy groups are intermediate in chelating ability. The extent of chelation also depends on the Lewis acid. Studies with a-alkoxy and (3-alkoxy aldehydes with lithium enolates found only modest diastereoselectivity.83... 

Alkyl and silyl nitronates are, in principle, /V-alkoxy and /V-silyloxynitrones, and they can react with alkenes in 1,3-dipolar cycloadditions to form /V-alkoxy- or /V-silyloxyisoxaz.olidine (see Scheme 8.25). The alkoxy and silyloxy groups can be eliminated from the adduct on heating or by acid treatment to form 2-isoxazolines. It should be noticed that isoxazolines are also obtained by the reaction of nitrile oxides with alkenes thus, nitronates can be considered as synthetic equivalents of nitrile oxides. Since the pioneering work by Torssell et al. on the development of silyl nitronates, this type of reaction has become a useful synthetic tool. Recent development for generation of cyclic nitronates by hetero Diels-Alder reactions of nitroalkenes is discussed in Section 8.3. 

Treatment of a-(benzotriazol-l-yl)alkyl thioethers 831 with ZnBr2 weakens the bond with benzotriazole, and the obtained complex 832 may partially dissociate to thionium cation 835 that can be trapped by even mild nucleophiles. Thus, trimethylsilyl cyanide added to the reaction mixture causes substitution of the benzotriazole moiety by the CN group to give a-(phenylthio)carbonitrile 834. In a similar manner, treatment with allylsilane leads to y,S-unsaturated thioether 833. Addition of species 835 to the double bond of a trimethylsilyl ot-arylvinyl ether followed by hydrolysis of the silyloxy group furnishes (i-(phenylthio)alkyl aryl ketones 836 (Scheme 132) <1996TL6631>. 

Silyltitanation of 1,3-dienes with Cp2Ti(SiMe2Ph) selectively affords 4-silylated r 3-allyl-titanocenes, which can further react with carbonyl compounds, C02, or a proton source [26]. Hydrotitanation of acyclic and cyclic 1,3-dienes functionalized at C-2 with a silyloxy group has been achieved [27]. The complexes formed undergo highly stereoselective addition with aldehydes to produce, after basic work-up, anti diastereomeric (3-hydroxy enol silanes. These compounds have proved to be versatile building blocks for stereocontrolled polypropionate synthesis. Thus, the combination of allyltitanation and Mukayiama aldol or tandem aldol-Tishchenko reactions provides a short access to five- or six-carbon polypropionate stereosequences (Scheme 13.15) [28],... 

Being less basic than the saturated analogs, vinyllithium as all other acyclic or cyclic 1-alkenyllithiums can be prepared from iodo or bromo and sometimes even chloro precursors using butyllithium or fert-butyUithium (Tables 12 and 13). Hetero-substituents such as dialkylamino, alkoxy and silyloxy groups or halogen atoms again accelerate the exchange process considerably (Table 14). This holds for 0-lithiated hydroxy or carboxy functions as well (Table 15). 

The reactions of nitrones with 165 have been described (277-279). In the approach described by Koskinen and co-workers (279), the bulky nitrone 166 was used in a reaction with 165 to give a 20 1 mixture of 167 and an unidentified diastereomer (Note Opposite enantiomers are shown here). Reactions of less bulky nitrones gave lower selectivities (277,278). Kim et al. (280,281) described reactions of 165 with silyl nitronates (Scheme 12.52). The configuration of the direct isoxazolidine products was not determined. Instead, diastereoselectivities of 66-88% de of 169 were found after elimination of the silyloxy group. The reaction of various nitrile oxides proceeded to give the same isoxazoline products 169 as obtained for nitronates (Scheme 12.52). For the reactions of 165 with various alkyl and aryl nitrile oxides 170, the products 169 were obtained with diastereoselectivities of 62-90% de (282-286). In a theoretical study, it was proposed that the... 

Enyne 7a having a silyloxy group on the alkyne gives cyclic compound 8a having a vinyl silyloxy moiety, which is converted into methyl ketone 9a by desilylation. In a similar manner, enyne 7b affords bicyclic methyl ketone 9b in 68% yield after deprotection of the silyl group. However, ynoate 7c and yne-phosphonate 7d do not give cyclized compounds. Ene-ynoate 12, which is obtained by treatment of enol ether 11 with BuLi affords cyclic enol ether 13 in good to moderate yields " (Scheme 4). 

Figure 5 Steric repulsion between ruthenium-carbene complex with the silyloxy group in trans-substituents.

Tetrahydrofurans 53 should be of synthetic interest because of the many natural products containing a bicyclic tetrahydrofuranoid skeleton or structural element [30]. The double bond would allow further synthetic transformations. While the chances of a regioselective isomerization of 46 to the allyl aminosulfoxonium salts 52 seemed to be good, the prospects of a cyclization of the latter with formation of 53 were considered to be less promising because of the poor nucleophilicity of the silyloxy group. 

Heteroatoni groups such as boron or silicon can activate or direct synthetic reactions. Use of such activation has become of major importance in organic syntheses. Examples in this volume are BORANES IN FUNCTIONALIZATION OF DIENES TO CYCLIC KETONES BICYCLO[3.3.1]NONAN-9-ONE and BORANES IN FUNCTIONALIZATION OF OLEFINS TO AMINES 3-PINANAMINE. Use of trimethylsilyl or trimethyl-silyloxy groups to activate a 2-butenone or a butadiene are illustrated by the preparations 3-TRIMETHYLSILYL-3-BUTEN-... 

The oxyanion of the enolate (or a silyloxy group) appears to speed up this reaction relative to an unadorned Claisen system, but an even more dramatic acceleration is seen when Cope systems have an oxyanion substituent on the tetrahedral carbon, as in the reaction 5.59 —> 5.61, which takes place at a... 

The isomeric 2-benzyl-3-methyl-pyrazole 1-oxide 193 reacts similarly to give the 3-iodomethyl-pyrazole 196. In this case, the 3-trimethylsilyloxy-methyl compound 197 is formed as a by-product. Most likely, the sily-loxymethyl compound 197 arises when the liberated silyloxyanion acts as a nucleophile replacing the silyloxy group in a regenerative fashion. The silyloxy compound 197 is readily hydrolyzed to hydroxymethyl-pyrazole 198. The 3-methyl-pyrazole 1-oxide 193 reacts five times faster than the 5-methyl isomer 189 as shown by a competition experiment (1992JCS(P1)2555). The iodomethyl-pyrazoles 192 and 196 are versatile starting materials for further transformations in the pyrazole side chain (Scheme 55). 

A synthetic method for the prepararation of cyclobutanones via an intramolecular cyclization of a ketone enolate has been reported.83 Enol triflates having a silyloxy group at the ft-position under the influence of TBAF give a cyclobutanone or a four-membered enol ether through rearrangement of the trifluoromethanesulfonyl group followed by an intramolecular C- or O-alkylation reaction (Scheme 49). 

---