Selenoxides preparation from selenides

Alkyl halides can be prepared from selenides and selenoxides.60 Oxidations - Active manganese dioxide oxidations have been reviewed.61... 

Unlike Af-hydroxy-2-thiopyridone, TV-hydroxy-2-selenopyridone is rather unstable and is easily oxidized. However, once photolytic treatment of O-acyl ester (53) of AMiydroxy-2-selenopyridone is carried out, the formed 2-pyridyl selenide is very useful. Thus, elimination of the selenoxides, formed from the oxidation of the selenide with mCPBA or ozone, proceeds effectively at low temperature. For example, eq. 8.23 shows the preparation of (l)-vinylglycine (56) from (L)-glutamic acid without racemization at all [70]. 

Cyclohexyl selenides 162 can be prepared from the 4-substituted cyclohexanones via the selenoketals and upon oxidation with chiral oxidants, compounds 163 were obtained in high yields and with excellent stereoselectivities. Some representative examples are summarized in Table 5 and it is obvious that only the Davies oxidant 158 is leading to high enantiomeric excesses in the product 163 whereas under Sharpless oxidation conditions no selectivity is obtained. The titanium complex formed in the Sharpless oxidant may promote the racemization of the intermediate selenoxide by acting as a Lewis acid catalyst, while the aprotic nature of the Davies oxidant 158 slows down racemization dramatically. 

Other convenient reagents for the imidation of sulfides and selenides are imidoiodanes such as A-(/>-tolylsulfonyl)-imino(phenyl)iodane (PhI=NTs).304 Unfortunately, these reagents are sometimes difficult to prepare due to their thermal sensitivity and some have even been claimed to be explosive.305 Selenimides are tricoordinate tetravalent compounds and can be isolated in optically active forms. They can be prepared from optically active selenoxides, a reaction which was shown to occur with an overall retention of stereochemistry.306 They can also be obtained by optical resolution of a diastereomeric selenimide and stereochemical issues including kinetics of epimerization by pyramidal inversion were studied in detail.307 Also the enantioselective imidation of prochiral selenides of type 179 is possible by using a combination of A-(/>-tolylsulfonyl)imino(phenyl)iodane (PhI=NTs) and a catalytic amount of... 

Thus, when cyclohexyl selenides 1, prepared from the corresponding 4-sub-stituted cyclohexanone via the selenoketals, were oxidized with various Davis and Sharpless oxidants, the chiral alkyl aryl 4-substituted cyclohexylidenemethyl ketones were obtained in excellent chemical yields with high enantiomeric excesses. Typical results are summarized in Table 4. In this asymmetric induction, of the substrate and the chiral oxidant employed were revealed to show a remarkable effect upon the enantioselectivity of the product. The use of a methyl moiety as instead of a phenyl moiety gave a higher ee value, probably due to the steric difference between the two groups bonded to the selenium atom of the substrate. The results indicate that the titanium complex of the Sharpless oxidant may promote the racemization of the chiral selenoxide intermediate by acting as a Lewis acid catalyst, whereas the racemization in the case of the Davis oxidant, which is aprotic in nature, is slow. 

The oxidation of the chiral ferrocenyl vinyl selenides, prepared from the optically active diferrocenyl diselenides and ethyl propiolate derivatives, with 1 molar equivalent of MCPBA under various conditions afforded the corresponding chiral selenoxides. The chiral selenoxides suffered in situ selenoxide elimination to afford the axially chiral allenecarboxyUc esters in moderate chemical yields with high enantioselectivities (Scheme 10). Typical results are shown in Table 5. The reaction temperature had a remarkable effect upon stereoselectivity and the lower temperature gave better results. The addition of molecular sieves (4 A) to the reaction system improved the stereoselectivity. Dichlo-romethane was revealed to be the solvent of choice. In other words, reaction conditions to suppress the racemization of a diastereomeric selenoxide intermediate were required. Asymmetric selenoxide elimination provides a new method for the preparation of the chiral allenecarboxyUc esters which have so far been prepared by optical resolution of the corresponding racemic acids. 

P-Hydroxy selenides are conveniently prepared from epoxides by treatment with sodium phenylse-lenide (Scheme 32) and by the addition of benzeneselenenic acid and its derivatives to alkenes (Scheme 33), - -" although in some cases these reactions are not regioselective. Useful phenylseleno -etherification and -lactonization reactions have been developed which can be regioselective (equation 42 and Schemes 34 and 35). -" " Selenide- and selenoxide-stabilized carbanions have been used in addition reactions with aldehydes and ketones, - and the reduction of a-seleno ketones also provides a route to P-hydroxy selenides. ... 

Although unable to metallate selenides, dialkyl amides are sufficiently strong to metallate phenylselenoacetals39,46 51) as well as methyl48,52) and phenyl 46,47,52) selenoorthoesters. They are also able to metallate selenoxides 4 9,11 53 55) and selenones 14). Finally selenoacetals are readily available 4,711,12 S6) from carbonyl compounds and selenols in the presence of a Lewis acid and selenoorthoesters have been prepared from orthoesters, selenols, and boron trifluoride etherate47,48,52). 

Selenides eliminate readily without a base. They are generally prepared from enolate anions by reaction with diphenyldiselenide or phenylselenyl bromide to give phenylselenides. The phenylselenides are oxidized with sodium periodate, hydrogen peroxide, or peracids to the selenoxides, which eliminate even at room temperature to afford the a,p-unsamrated ketones and esters [107]. 

Di-a-naphthyl selenium dibromide, (C10H7)2SeBr2, is prepared in the usual manner. It forms wThite needles, melting at 183° C. with decomposition, soluble in amyl alcohol but best recrystallised from carbon disulphide. The halogen may be removed by alkali, but only di-a-naphthyl selenide results, no selenoxide being isolated as in the preceding cases. 

Treatment of the hydronitrates in aqueous solution with sodium carbonate causes evolution of carbon dioxide. Evaporation to dryness, followed by extraction with alcohol or benzene, then yields oils which are probably the selenoxides. These oils with concentrated hydrochloric acid are converted into white solids, crystallisable from benzene, xylene, alcohol or dry ether. These solids are the dichlorides of the original selenides, and when prepared by this method their melting-points are as follows Phenyl methyl selenium dichloride, M.pt. 122° C. phenyl ethyl selenium dichloride, M.pt. 64° to 65° C. diphenyl selenium dichloride, M.pt. 142° C. 

Certain alkylaryl selenides can be prepared by the electrophilic selenylation of eno-lates (Figure 4.12 also see Table 10.4). With a subsequent H2Oz oxidation to produce the selenoxide followed by the elimination of Ph—Se—OH, one proceeds in a total of two synthetic steps from a carbonyl or carboxyl compound to its a,/3-unsaturated analogue. 

Propargyl phenyl selenide is a versatile multifunctional acrylate synthon, as shown in Scheme 12. The (Uanion is prepared and reacted successively with an alkylating agent (R— X) and an electrophile (E ). The oxidative rearrangement of the propargylic selenoxide (35) to an allenic selenenate (36), and Aence to the a-phenylselenoenone (37), forms the keystone of this synthetic method, and overall yields from propargyl phenyl selenide are in the range of 38-68%. Further elaboration of (37) is possible... 

Sulfide and selenide precursors for 2,3-rearrangements can be obtained stereochemically pure by chal-cogeno-etherifications (equation 78). From these precursors thio-(211) and seleno-(211) were prepared by oxidation. While the sulfoxide refused to rearrange to alcohol (212) under various conditions, the selenoxide did so even at 0 °C. Here, the extra driving force of selenoxide vs. sulfoxide rearrangements was an essential it pushed the selenoxide through a transition state obviously too sterically hindered for the less reactive sulfur analog. 

Reich has now described the ready preparation of a-lithio-selenides and -selenoxides, which smoothly condense with aldehydes and ketones. The resultant /3-hydroxy-selenides and -selenoxides can be reductively eliminated under very mild conditions to give tetrasubstituted olefins, which are not readily available from the Wittig reaction. The /3-hydroxyselenides can be converted into olefins under milder conditions than their sulphur equivalents, using methane-sulphonyl chloride in triethylamine. 

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