Addition, cyclo oxidative

Bixchler Napiralski, Dieckmann cyclization [15], Suzuki reaction [48], Wittig reaction, ozonolysis, condensation, esterification, nucleophilic substitution [49], Henry reaction, 1.3-dipolar cyclo-addition, electrophilic addition [50], oxidation chloride -> aldehyde [50], sulfide —> sulfone [51], alcohol —> ketone, Arbuzov reaction (phosphine-phosphorox-ide) [52], reduction hydration [45], ester -> alcohol [49, 53]... 

An interesting new method for the conversion of [I, y-epoxy sulfones (82) to cyclo-alkenones (85) has been developed61. It includes the addition of alkyllithium to y-hydroxy-a,/ -unsaturated sulfones generated from 82 and the alkylation of sulfonyl carbanion thus formed. Oxidation of the resulting y-hydroxy sulfone to 84 followed by elimination of benzenesulfinic acid gives the desired product 85 in good yields (equation 72)61. 

In 2000, it was proposed that the regioselectivity of the [3 + 2] cycloaddition of fullerenes could be modified under microwave irradiation. Under conventional heating, N-methylazomethine yhde and fullerene-(C7o) gave three different isomeric cycloadducts because of the low symmetry of C70 vs. Ceo. Using microwave irradiation and o-dichlorobenzene as a solvent, only two isomers were obtained, the major cycloadduct 114 being kinetically favored (Scheme 39) [75]. The same authors had previously reported the 1,3-dipolar cyclo addition of pyrazole nitrile oxides, generated in situ, to Geo under either conventional heating or microwave irradiation. The electrochemical characteristics of the cycloadduct obtained with this method made this product a candidate for photophysical apphcations [76]. 

The stereochemistry of dienes has been found to have a pronounced effect in the concerted cyclo-additions with benzyne 64>65h A concerted disrotatory cyclo-addition of tetrafluorobenzyne, leading for example with trans- (3-methylstyrene to (63, R = Me), is likely and in accord with the conservation of orbital symmetry 68>. However while the electro-cyclic rearrangement of (63, R = H) to (65, R = H) is not allowed, base catalysed prototropic rearrangement is possible. A carbanion (64, R = H) cannot have more than a transient existence in the reaction of tetrafluorobenzyne with styrene because no deuterium incorporation in (65) was detected when either the reaction mixture was quenched with deuterium oxide or when the reaction was conducted in the presence of a ten molar excess of deuteriopentafluorobenzene. 

When methanol was used to rinse a pestle and mortar which had been used to grind coarse chromium trioxide, immediate ignition occurred due to vigorous oxidation of the solvent. The same occurred with ethanol, 2-propanol, butanol and cyclo-hexanol. Water is a suitable cleaning agent for the trioxide [1]. For oxidation of sec-alcohols in DMF, the oxide must be finely divided, as lumps cause violent local reaction on addition to the solution [2]. Use of methanol to reduce the Cr(VI) oxide to a Cr(III) derivative led to an explosion and fire [3], The ignitability of the butanols decreases from n -through sec- to iert-butanol [4],... 

Stone and co-workers (16) recently announced that they had isolated and characterized a novel class of crystalline platinum(II) complexes prepared at room temperature by oxidative addition of hydrogen or of R3SiH (R3 = Me2Et, Me2CH2Ph, Cl3, or Et3)to (cyclo-C6H1, P Pt (C2H4. All these complexes were found to be excellent catalysts for hydrosilation... 

Four-component annelation to alkenolides. Posner et al. have reported a one-pot three-step annelation of cycloalkenones to provide, after oxidation, four-atom enlarged macrolides. Thus Michael addition of tributyltinlithium to cyclo-hexenone (1) and Michael addition of the resulting enolate to ethyl vinyl ketone followed by an aldol reaction results in cyclization to a bicyclic hemiketal (2), which is oxidized by Pb(OAc)4 to an unsaturated 10-membered lactone (3). 

This chapter will begin with a discussion of the role of chiral copper(I) and (II) complexes in group-transfer processes with an emphasis on alkene cyclo-propanation and aziridination. This discussion will be followed by a survey of enantioselective variants of the Kharasch-Sosnovsky reaction, an allylic oxidation process. Section II will review the extensive efforts that have been directed toward the development of enantioselective, Cu(I) catalyzed conjugate addition reactions and related processes. The discussion will finish with a survey of the recent advances that have been achieved by the use of cationic, chiral Cu(II) complexes as chiral Lewis acids for the catalysis of cycloaddition, aldol, Michael, and ene reactions. 

Starting material which, upon oxidation with PSP, gave aldehydes. These were in turn condensed with primary hydroxylamines, promoted by polymer-bound acetate, to produce nitrones. The nitrones assembled using either method then underwent 1,3-dipolar cyclo-addition reactions with various alkenes to give the corresponding isoxazolidines (Scheme 2.46 and 2.47). 

The fact that complex 38 does not react further - that is, it does not oxidatively add the N—H bond - is due to the comparatively low electron density present on the Ir center. However, in the presence of more electron-rich phosphines an adduct similar to 38 may be observed in situ by NMR (see Section 6.5.3 see also below), but then readily activates N—H or C—H bonds. Amine coordination to an electron-rich Ir(I) center further augments its electron density and thus its propensity to oxidative addition reactions. Not only accessible N—H bonds are therefore readily activated but also C—H bonds [32] (cf. cyclo-metallations in Equation 6.14 and Scheme 6.10 below). This latter activation is a possible side reaction and mode of catalyst deactivation in OHA reactions that follow the CMM mechanism. Phosphine-free cationic Ir(I)-amine complexes were also shown to be quite reactive towards C—H bonds [30aj. The stable Ir-ammonia complex 39, which was isolated and structurally characterized by Hartwig and coworkers (Figure 6.7) [33], is accessible either by thermally induced reductive elimination of the corresponding Ir(III)-amido-hydrido precursor or by an acid-base reaction between the 14-electron Ir(I) intermediate 53 and ammonia (see Scheme 6.9). 

Early work on the mechanisms of alkene cleavage by RuO has been briefly reviewed [50]. In the oxidation of 1,5-dienes to cA-tetrahydrofurandiols by RuO / aq. Na(10 )/EtOAc-acetone it is likely that there is cyclo-addition of RuO to one double bond of two 1,5-diene molecules to give a Ru(lV) diester this is oxidised by Na(lO ) to a Ru(Vl) diester, which is then hydrolysed to the organic product (Fig. 3.12) [345], and indeed Ru(Vl) diesters RuOlO R) have been isolated (Fig. 1.31) [323, 346]. ... 

On addition of S04 to the triple bond in the lO-member cycloalkyne 24 and cyclo-aUcynone 27, a nonchain, and anionic, self-terminating radical cyclization cascade is induced. In the former reaction (equation 22) the bicyclic ketones 25 and 26 are formed, and in the latter reaction (equation 23) the a,/3-epoxy ketones 28 and 29 are formed in good yields. Because of the difficulty of oxidizing isolated triple bonds, 804 does not react as an electron-transfer reagent in these reactions but acts as a donor of atomic oxygen. 

In a side-reaction 10-15% carboxylic acids are produced by oxidative cleavage of the ketone enolates. The cleavage is favoured by higher temperatures e.g. cyclo-hexanol leads to 80% cyclohexanone and 16% adipic acid at 25 °C, whilst at 80 °C 5% ketone and 42% diacid are found. These acidic by-products are easily separated, since they remain in the alkaline solution during workup. The oxidation of 6 gave the acetal 7 as main product (28%) together with 4% of the ketone 8 and 56% of unchanged 6. The acetal 7 is probably formed by nucleophilic addition of the alcohol 6 at the activated triple bond of ketone 8. 

Nitrile oxide J -I- 2 cycloaddition.1 A key step in a recent stereospecific synthesis of biotin (6) from cycloheptene (1) is an intramolecular [3 + 2]cyclo-addition of a nitrile oxide (a), obtained by dehydration of a primary nitro compound (3), preferably with phenyl isocyanate. This cycloaddilion is more efficient than the well-known olefinic nitrone cycloaddition. The carbon atoms in 6 derived from cycloheptene are marked with asterisks. 

Early attempts to utilize I as a donor for a chromium sandwich complex did not meet with success268, but recent studies have now provided several /6-chromium(0) complexes 64- 99-200. Whereas unsubstituted cycloproparenes undergo oxidative addition of the ring to the metal followed by carbon monoxide insertion (Section V.B.4), the l,l-bis(trimethylsilyl) derivatives do not. Instead, reactivity is transferred to the arene and, with tris(acetoni-trile)tricarbonylchromium, -complexes are formed at the ring remote from the cyclo-proparene moiety (equation 28). However, the 1,1 -disilyl derivative of 1 does not react and... 

Cyclo additions, such as Diels-Alder reactions of H2(/l-vinyl-Por), and 0s04 oxidation occur at Cp—Cp, while radical reactions, Tl(OCOCF3)3 oxidation and catalytic hydrogenations result in addition to the meso positions.2,19... 

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