Silyl nitronate

Several approaches based on nitro-aldol for the synthesis of amino sugars have been reported Alumina-catalyzed reaction of methyl 3- nitropropanoate with O-benzyl-o-lactaldehyde gives the o-ribo-nitro-aldol fanti, and isomeri in 63% yield, which is converted into L-dannosamine fsee Secdon 3 3 Jager and coworkers have reported a short synthesis of L-acosamine based on the stereoselective nitro-aldol reaction of 2-O-benzyl-L-lactaldehyde with 3-nitropropanal dimethyl acetal as shovm in Scheme 3 10 The stereoselecdve nitro-aldol reacdon is carried ont by the silyl nitronate approach as discussed in Secdon 3 3... 

Method G Highruiri-selecdvity is also observed in the fluoride-catalyzed reacdonof silyl nitronates v/ith aldehydes. Trialkyl silyl nitronates are prepared in good yield from primary nitroalkanes by consecndve treatment v/ith iithiiim dusopropylamide and trialkylsilyl chloride at -78 C in THF. 

Recently, solicon-tethered thastereoselecdve ISOC reactions have been reported, in which effective control of remote acyclic asymmetry can be achieved fEq 8 91) Whereas ISOC occur stereoselecdvely, INOC proceeds v/ith significandy lower levels of diastereoselecdon The reaction pathways presented in Scheme 8 28 suggest a plausible hypothesis for the observed difference of stereocontrol The enhanced selecdvity in reacdons of silyl nitronates may be due to l,3- illylic strain The near-linear geometry of nitnle oxides precludes such differendadng elements fScheme 8 28 ... 

Intramolecular Silyl Nitronate-Olefin Cycloaddition (ISOC)... 

Although nitrile oxide cycloadditions have been extensively investigated, cycloadditions of silyl nitronates, synthetic equivalent of nitrile oxides in their reactions with olefins, have not received similar attention. Since we found that the initial cycloadducts, hl-silyloxyisoxazolidines, are formed with high degree of stereoselectivity and can be easily transformed into isoxazolines upon treatment with acid or TBAF, intramolecular silylnitronate-olefin cycloadditions (ISOC) have emerged as a superior alternative to their corresponding INOC reactions [43]. Furthermore, adaptability of ISOC reactions to one-pot tandem sequences involving 1,4-addition and ISOC as the key steps has recently been demonstrated [44]. 

One-pot tandem sequences involving 1,4-addition and ISOC as the key steps have been developed for the construction of N and 0 heterocycles as well as of carbocycles [44]. In this sequence, the nitronate arising from 1,4-addition to an a, -unsaturated nitro alkene is trapped kinetically using trimethyl silyl chloride (TMSCl). The resulting silyl nitronate underwent a facile intramolecular 1,3-dipolar cycloaddition with the unsaturated tether (e.g.. Schemes 20-22). 

ISOC reaction was employed to synthesize substituted tetrahydrofurans 172 fused to isoxazolines (Scheme 21) [44b]. The silyl nitronates 170 resulted via the nitro ethers 169 from base-mediated Michael addition of allyl alcohols 168 to nitro olefins 167. Cycloaddition of 170 followed by elimination of silanol provided 172. Reactions were conducted in stepwise and one-pot tandem fashion (see Table 16). A terminal olefinic Me substituent increased the rate of cycloaddition (Entry 3), while an internal olefinic Me substituent decreased it (Entry 4). 

High levels of diastereocontrol in an ISOC reaction were induced by a stereogenic carbon center that bears a Si substituent (Scheme 23) [55]. For instance, conversion of nitro alkenes (e.g., 199) to j3-siloxyketones (e.g., 203) has been accomplished via a key ISOC reaction-reduction sequence with complete control of 1,5-relative stereochemistry. The generality of the ISOC reaction of a silyl nitronate with a vinylsilane was demonstrated with seven other examples. Corresponding INOC reaction proceeded with lower stereoselectivity. 

Thioethers 210 are smoothly formed upon cyclization of silyl nitronates 209, generated in situ from the nitro compounds 208, on treatment with N,0-bis(trimethylsilyl)acetamide (BSA, Scheme 24) [57]. Fluorodesilylation of 210 gave the AT-oxide 212, presumably via highly reactive aldehyde 211, which was reduced to the target compound actinidine 213 in an overall 27% yield. 

On treatment of trialkylsilyl nitronates 1043 with MeLi, LiBr, or BuLi in THF the resulting nitrile oxide intermediates 1044 afford, in dilute THF solution (R=Me) the ketoximes 1045 in ca 50-60% yield, whereas in concentrated THF solution the O-silylated hydroxamic acids 1046 are obtained as major products [144] (Scheme 7.35). Analogously, the silyl nitronate 1047 reacts with the 2,3,4,6-tetra-O-acetyl-/ -D-glucopyranosyl thiol/triethylamine mixture to afford, via the thiohydroxi-mate 1048, in high yield, a mixture of oximes 1049 which are intermediates in the synthesis of glucosinolate [145] (Scheme 7.35). 

The Michael addition of allyl alcohols to nitroalkenes followed by intramolecular silyl nitronate olefin cycloaddition (Section 8.2) leads to functionalized tetrahydrofurans (Eq. 4.15).20... 

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. 

A series of 3-substituted-2-isoxazoles are prepared by the following simple procedure in situ conversion of nitroalkane to the silyl nitronate is followed by 1,3-dipolar cycloaddition to produce the adduct, which undergoes thermal elimination during distillation to furnish the isoxazole (Eq. 8.74). 5 Isoxazoles are useful synthetic intermediates (discussed in the chapter on nitrile oxides Section 8.2.2). Furthermore, the nucleophilic addition to the C=N bond leads to new heterocyclic systems. For example, the addition of diallyl zinc to 5-aryl-4,5-dihydroi-soxazole occurs with high diastereoselectivity (Eq. 8.75).126 Numerous synthetic applications of 1,3-dipolar cycloaddition of nitronates are summarized in work by Torssell and coworker.63a... 

Eguchi and Ohno have used silyl nitronate induced 1,3-dipolar cycloaddition for functionalization of fullerene C60 (Eq. 8.76).127a Nitrile oxides also undergo 1,3-dipolar cycloaddition... 

Hassner and coworkers have developed a one-pot tandem consecutive 1,4-addition intramolecular cycloaddition strategy for the construction of five- and six-membered heterocycles and carbocycles. Because nitroalkenes are good Michael acceptors for carbon, sulfur, oxygen, and nitrogen nucleophiles (see Section 4.1 on the Michael reaction), subsequent intramolecular silyl nitronate cycloaddition (ISOC) or intramolecular nitrile oxide cycloaddition (INOC) provides one-pot synthesis of fused isoxazolines (Scheme 8.26). The ISOC route is generally better than INOC route regarding stereoselectivity and generality. 

The use of silylketals derived from allylic alcohols and 1-substituted nitroethanols for the stereocontrolled synthesis of 3,4,5-trisubstituted 2-isoxazolines via intramolecular 1,3-dipolar cycloaddition has been demonstrated. Here again, the use of silyl nitronates (ISOC) increases the level of selectivity compared to INOC (Eq. 8.92).145... 

Isoxazolines A-oxides have been synthesized from primary aliphatic nitro compounds and alkenes by a two-step procedure consisting of 1,3-DC of a 1-halo-substituted silyl nitronate followed by halosilane elimination <06S2265>. 

The second step involves silylation of halonitroalkanes (29) with standard silylating agents SiCl/Et3N(Si is Me Si or Me2Bu Si). Silyl nitronates 30 can be detected by physicochemical methods. 

Synthesis of Dialkylboryl Nitronates Approaches to the synthesis of boryl nitronates are similar to the strategy for the synthesis of silyl nitronates developed in more detail (see Section 3.2.3). However, only four studies have dealt with the synthesis of boryl nitronates (217, 229-231). The absence of interest in this class of compounds is apparently attributed to the fact that they are not involved in 1,3-dipolar cycloaddition reactions and, consequently, are unlikely to find use in organic synthesis. 

In studies of alkyl- or silyl nitronates, the problem of comparison of covalent and ionic stmctures is not urgent because it is impossible to imagine a stable product containing alkyl- or trialkylsilyl cations. However, this is not so evident for other elementorganic nitronates, and special studies were required to solve these questions (see, e.g., Ref. 232). 

The UV spectra of nitronates, which are not functionalized at the a-C atom, have an intense absorption at 230 to 240 nm, which is very similar in characteristics to UV absorption of salts of nitro compounds and solutions of aci-nitro compounds in protic solvents. Since standard alkyl- or silyl nitronates cannot have ionic structures, the presence of the above mentioned absorption in the UV spectra of nitronates, unambiguously confirms, that these compounds have the structures of O-esters. 

It should be noted that selective silylation of the carbonyl group bound to the atom, which bears the nitro group, was documented (see products 60 Scheme 3.60, Eq. 3 (152, 214, 215),). It cannot be ruled out that silylation of other a-functionalized AN also affords initially intermediates silylated at the functional group, and that these intermediates rapidly and irreversibly isomerize into the respective thermodynamically preferable silyl nitronates. 

By contrast, softer nucleophiles, such as thiols (111), evidently do react with SENAs at the a-C atom (307) (see Scheme 3.94). This interpretation is confirmed by a substantial difference in the configuration of thiohydroxamate 112a isolated in the reaction with silyl nitronate (a) and analogous product 112b (b) prepared from authentic nitrile oxide. 

All reactions initially produce silyl nitronates, which react with nucleophiles to give nitroso intermediates A. The latter give products 114 to 116 either during the reaction or upon aqueous treatment. 

Second, nitroxyl radicals, which are generated either by a one-electron oxidation of SENAs (Eq. 1, Scheme 3.98) or by the addition of radical species to silyl nitronates (Eq. 2, Scheme 3.98), are rather stable and, consequently, can act as kinetically independent species. 

This reaction was studied in most detail by Narasaka and coworkers (313). These authors demonstrated that silyl nitronates can be oxidized by different triva-lent manganese salts (acetate, acetylacetonate, etc.), but Mn(pic)3 is the oxidizing agent of choice. 

I. Intermolecular [3+2]-Addition of Nitronates to Olefins Of all known types of nitronates (see Section 3.2), alkyl- and silyl nitronates as well as cyclic C5-C6 nitronates are involved in [3+ 2]-cycloaddition reactions. Detailed comparative kinetic studies for different types of nitronates have not been reported. However, a few data (162, 336, 337) allow one to deduce some sequences (Chart 3.10). 

Silyl Nitronates The characteristic features of the behavior of SENAs in [3+ 2]-addition reactions (75, 133, 175-177, 185, 186, 189, 201a, 203, 205, 206, 216, 355-362c) are virtually identical to those of acyclic alkyl nitronates considered in the previous section. As mentioned above, minor but more reactive Z-tautomers of SENAs derived from primary AN can be detected by cycloaddition reactions (see Section 3.3.4.1 and Scheme 3.128). 

Here two facts can be mentioned. For example, cycloaddition of nitronate (Me02C)CH=N(0)0SiMe3 to ethylene was observed (203), whereas its O -methyl analog does not react with ethylene. It is hardly probable that this fact is due to the high reactivity of the silyl nitronate. More likely, the negative result for alkyl nitronate is attributed to low stability of this derivative. 

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