Silylation Chapter selective

The Diels-Alder reaction outlined above is a typical example of the utilization of axially chiral allenes, accessible through 1,6-addition or other methods, to generate selectively new stereogenic centers. This transfer of chirality is also possible via in-termolecular Diels-Alder reactions of vinylallenes [57], aldol reactions of allenyl eno-lates [19f] and Ireland-Claisen rearrangements of silyl allenylketene acetals [58]. Furthermore, it has been utilized recently in the diastereoselective oxidation of titanium allenyl enolates (formed by deprotonation of /3-allenecarboxylates of type 65 and transmetalation with titanocene dichloride) with dimethyl dioxirane (DMDO) [25, 59] and in subsequent acid- or gold-catalyzed cycloisomerization reactions of a-hydroxyallenes into 2,5-dihydrofurans (cf. Chapter 15) [25, 59, 60],... 

Because of the polyfunctional nature of carbohydrates, protective-group strategy plays an important role in synthetic methodology involving this class of compounds. In the present Chapter, results are described from a study of the utility of N-trimethylsilyl- and N-tert-butyldimethylsilyl-phthalimide for the selective silylation of primary hydroxyl groups in carbohydrates. Also described, is a new, facile method for cleavage of acetals and dithioacetals in carbohydrate derivatives the method involves treatment of the derivatives with a dilute solution of iodine in methanol. 

This chapter is divided into four major sections. The first (Section 2.1) will deal with the structure of both alkoxy and silyl nitronates. Specifically, this section will include physical, structural, and spectroscopic properties of nitronates. The next section (Section 2.2) describes the mechanistic aspects of the dipolar cycloaddition including both experimental and theoretical investigations. Also discussed in this section are the regio- and stereochemical features of the process. Finally, the remaining sections will cover the preparation, reaction, and subsequent functionalization of silyl nitronates (Section 2.3) and alkyl nitronates (Section 2.4), respectively. This will include discussion of facial selectivity in the case of chiral nitronates and the application of this process to combinatorial and natural product synthesis. 

Exactly the same sort of mechanism accounts for the reactions of aryl silanes with electrophiles under Friedel-Crafts conditions. Instead of the usual rules governing ortho, meta, and para substitution using the directing effects of the substituents, there is just one rule the silyl group is replaced by the electrophile at the same atom on the ring—this is known as ipso substitution. Actually, this selectivity comes from the same principles as those used for ordinary aromatic substitution (Chapter 22) the electrophile reacts to produce the most stable cation—in this case (3 to silicon. Cleavage of the weakened C-Si bond by any nucleophile leads directly to the ipso product. 

Lithium enolates 85 and silyl enol ethers 86 are probably widest in application in modern organic synthesis. The basic rules of selectivity were laid down in chapters 2-4 where many examples were given. We shall simply summarise the position and add some extra versatility from chapters 5-9. These two methods must be taken together because easy interconversion means that a way of making one is a way of making another. In addition, the silyl enol ethers 86 are a source of naked enolates 87 when fluoride is used to remove silicon in the absence of a metal cation. Tetra-alkyl ammonium fluorides such as TBAF (Bu4N+ I ) are usually used. 

We have seen that vinyl silanes can be prepared by hydrosilylation of alkynes by three different mechanisms giving good control over geometry of these inevitably terminal vinyl silanes. Vinyl silanes are stable compounds and can be isolated, unlike most of the vinyl metals we have seen so far, and other ways of making vinyl silanes allow the more-or-less controlled synthesis of mono-or trisubstituted compounds with reasonable control over selectivity. These include the Peterson reaction with two SiMe3 groups on the same carbon atom 183 and, more relevant to this chapter, reactions of vinyl lithiums with silyl chlorides.44... 

Conjugate addition of the complete allylic alcohol fragment is possible with the mixed cuprate reagents 33 prepared by asymmetric reduction (chapter 26) of acetylenic ketones 29 to give the alcohols 30, protection as a silyl ether 31 and hydroboration-iodination. Lithiation and reaction with hexynyl copper (I) gives the mixed cuprate 33 from which the less stable anion is transferred selectively to an enone.3 This approach has been widely used in the synthesis of prostaglandins. 

Secondary amines can be formed from the same starting materials 136 by tandem Grignard addition andborohydride reduction.43 The reduction shows goodFelkin-Anh selectivity (chapter 21) and the silyl group can be cleaved from the products 140, as they are safe from racemisation, to give a range of amino alcohols 141. Compounds like these can also be made by asymmetric amino-hydroxylation (chapter 25). 

Largely stimulated by the synthesis of 3-lactam antibiotics, there have been widespread investigations into the stereochemical aspects of imine condensations, mainly involving reactions of enolates of carboxylic acid derivatives or silyl ketene acetals. In analogy to the aldol condensation, stereoselectivity of imine condensations will be discussed in terms of two types in this chapter (i) simple dia-stereoselectivity or syn-anti selectivity, when the two reactants are each prochiral (equation 12) and (ii) diastereofacial selectivity, when a new chiral center is formed in the presence of a pre-existing chiral center in one of the reactants (e.g. equation 13). The term asymmetric induction may be used synonymously with diastereofacial selectivity when one of the chiral reactants is optically active. For a more explicit explanation of these terms, see Heathcock s review on the aldol condensation. ... 

Interligand asymmetric induction. Group-selective reactions are ones in which heterotopic ligands (as opposed to heterotopic faces) are distinguished. Recall from the discussion at the beginning of this chapter that secondary amines form complexes with lithium enolates (pp 76-77) and that lithium amides form complexes with carbonyl compounds (Section 3.1.1). So if the ligands on a carbonyl are enantiotopic, they become diastereotopic on complexation with chiral lithium amides. Thus, deprotonation of certain ketones can be rendered enantioselective by using a chiral lithium amide base [122], as shown in Scheme 3.23 for the deprotonation of cyclohexanones [123-128]. 2,6-Dimethyl cyclohexanone (Scheme 3.23a) is meso, whereas 4-tertbutylcyclohexanone (Scheme 3.23b) has no stereocenters. Nevertheless, the enolates of these ketones are chiral. Alkylation of the enolates affords nonracemic products and O-silylation affords a chiral enol ether which can... 

Alkynes provide one of the most fruitful sources of vinylsilanes. Terminal and internal alkynes can be treated directly with silyl cuprates, or with hydridosilanes (hydrosilylation—see Chapter 17) problems of regio-selectivity arise in internal cases. Alternatively, terminal alkynes can be converted into the corresponding alkynylsilanes (Chapter 7) such species react regioselectively with a wide range of organometallic reagents, and they can also be reduced catalytically. These processes are summarized here for terminal alkynes ... 

The best alkylating agents for silyl enol ethers are tertiary alkyl halides they form stable carbocations in the presence of Lewis acids such as TiCl4 or SnCl4. Most fortunately, this is just the type of compound that is unsuitable for reaction with lithium enolates or enamines, as elimination results rather than alkylation a nice piece of complementary selectivity. Below is an example the alkylation of cyclopentanone with 2-chloro-2-methylbutane. The ketone was converted to the trimethylsilyl enol ether with triethylamine and trimethylsilylchloride we discussed this step on p. 466 (Chapter 20). Titanium tetrachloride in dry dichloromethane promotes the alkylation step. 

In the area of 2, 3 -didehydro-2, 3 -dideoxynucleosides, a new route to compounds of this type in the pyrimidine series is outlined in Scheme 4. The thioglycoside 54 was produced directly from deoxyribose and thiophenol in acidic conditions, and the condensations to form the nucleoside derivatives were P-selective by about 2 l/ A full account has been given of the formation of 2, 3 -didehydro-2, 3 -dideoxy systems from 2, 3 -dimesylates, protected at 0-5, by treatment with telluride anion (see Vol. 27, p. 247)7 Treatment of the furanoid glycal 55, made by cyclization of an acetylenic alcohol (Chapter 13), with silylated thymine in the presence of iodine, followed by sodium methoxide, provides a new route to d4T (56)7 A new synthesis of d4T (56) from 5-methyluridine has also been described, as has a route to d4T labelled with at C-1, which starts from [l- C]-ribose and proceeds via [r- C]-5-methyluridine, convertible in very high yield to [l - C]-d4T. ... 

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